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19442b86 | 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: AliUnfolding.cxx 31168 2009-02-23 15:18:45Z jgrosseo $ */ | |
17 | ||
18 | // This class allows 1-dimensional unfolding. | |
19 | // Methods that are implemented are chi2 minimization and bayesian unfolding. | |
20 | // | |
21 | // Author: Jan.Fiete.Grosse-Oetringhaus@cern.ch | |
22 | ||
23 | #include "AliUnfolding.h" | |
24 | #include <TH1F.h> | |
25 | #include <TH2F.h> | |
26 | #include <TVirtualFitter.h> | |
27 | #include <TMath.h> | |
28 | #include <TCanvas.h> | |
29 | #include <TF1.h> | |
9e065ad2 | 30 | #include <TExec.h> |
31 | #include "Riostream.h" | |
32 | #include "TROOT.h" | |
33 | ||
34 | using namespace std; //required for resolving the 'cout' symbol | |
19442b86 | 35 | |
36 | TMatrixD* AliUnfolding::fgCorrelationMatrix = 0; | |
95e970ca | 37 | TMatrixD* AliUnfolding::fgCorrelationMatrixSquared = 0; |
19442b86 | 38 | TMatrixD* AliUnfolding::fgCorrelationCovarianceMatrix = 0; |
39 | TVectorD* AliUnfolding::fgCurrentESDVector = 0; | |
40 | TVectorD* AliUnfolding::fgEntropyAPriori = 0; | |
95e970ca | 41 | TVectorD* AliUnfolding::fgEfficiency = 0; |
9e065ad2 | 42 | |
43 | TAxis* AliUnfolding::fgUnfoldedAxis = 0; | |
44 | TAxis* AliUnfolding::fgMeasuredAxis = 0; | |
19442b86 | 45 | |
46 | TF1* AliUnfolding::fgFitFunction = 0; | |
47 | ||
48 | AliUnfolding::MethodType AliUnfolding::fgMethodType = AliUnfolding::kInvalid; | |
49 | Int_t AliUnfolding::fgMaxInput = -1; // bins in measured histogram | |
50 | Int_t AliUnfolding::fgMaxParams = -1; // bins in unfolded histogram = number of fit params | |
51 | Float_t AliUnfolding::fgOverflowBinLimit = -1; | |
52 | ||
53 | AliUnfolding::RegularizationType AliUnfolding::fgRegularizationType = AliUnfolding::kPol1; | |
54 | Float_t AliUnfolding::fgRegularizationWeight = 10000; | |
55 | Int_t AliUnfolding::fgSkipBinsBegin = 0; | |
56 | Float_t AliUnfolding::fgMinuitStepSize = 0.1; // (usually not needed to be changed) step size in minimization | |
9e065ad2 | 57 | Float_t AliUnfolding::fgMinuitPrecision = 1e-6; // minuit precision |
03650114 | 58 | Int_t AliUnfolding::fgMinuitMaxIterations = 1e6; // minuit maximum number of iterations |
95e970ca | 59 | Bool_t AliUnfolding::fgMinimumInitialValue = kFALSE; // set all initial values at least to the smallest value among the initial values |
60 | Float_t AliUnfolding::fgMinimumInitialValueFix = -1; | |
9e065ad2 | 61 | Bool_t AliUnfolding::fgNormalizeInput = kFALSE; // normalize input spectrum |
95e970ca | 62 | Float_t AliUnfolding::fgNotFoundEvents = 0; |
63 | Bool_t AliUnfolding::fgSkipBin0InChi2 = kFALSE; | |
19442b86 | 64 | |
65 | Float_t AliUnfolding::fgBayesianSmoothing = 1; // smoothing parameter (0 = no smoothing) | |
651e2088 | 66 | Int_t AliUnfolding::fgBayesianIterations = 10; // number of iterations in Bayesian method |
19442b86 | 67 | |
68 | Bool_t AliUnfolding::fgDebug = kFALSE; | |
69 | ||
95e970ca | 70 | Int_t AliUnfolding::fgCallCount = 0; |
71 | ||
9e065ad2 | 72 | Int_t AliUnfolding::fgPowern = 5; |
73 | ||
74 | Double_t AliUnfolding::fChi2FromFit = 0.; | |
75 | Double_t AliUnfolding::fPenaltyVal = 0.; | |
76 | Double_t AliUnfolding::fAvgResidual = 0.; | |
77 | ||
78 | Int_t AliUnfolding::fgPrintChi2Details = 0; | |
79 | ||
80 | TCanvas *AliUnfolding::fgCanvas = 0; | |
81 | TH1 *AliUnfolding::fghUnfolded = 0; | |
82 | TH2 *AliUnfolding::fghCorrelation = 0; | |
83 | TH1 *AliUnfolding::fghEfficiency = 0; | |
84 | TH1 *AliUnfolding::fghMeasured = 0; | |
85 | ||
19442b86 | 86 | ClassImp(AliUnfolding) |
87 | ||
88 | //____________________________________________________________________ | |
89 | void AliUnfolding::SetUnfoldingMethod(MethodType methodType) | |
90 | { | |
91 | // set unfolding method | |
92 | fgMethodType = methodType; | |
93 | ||
94 | const char* name = 0; | |
95 | switch (methodType) | |
96 | { | |
97 | case kInvalid: name = "INVALID"; break; | |
98 | case kChi2Minimization: name = "Chi2 Minimization"; break; | |
99 | case kBayesian: name = "Bayesian unfolding"; break; | |
100 | case kFunction: name = "Functional fit"; break; | |
101 | } | |
102 | Printf("AliUnfolding::SetUnfoldingMethod: %s enabled.", name); | |
103 | } | |
104 | ||
105 | //____________________________________________________________________ | |
106 | void AliUnfolding::SetCreateOverflowBin(Float_t overflowBinLimit) | |
107 | { | |
108 | // enable the creation of a overflow bin that includes all statistics below the given limit | |
109 | ||
110 | fgOverflowBinLimit = overflowBinLimit; | |
111 | ||
112 | Printf("AliUnfolding::SetCreateOverflowBin: overflow bin limit set to %f", overflowBinLimit); | |
113 | } | |
114 | ||
115 | //____________________________________________________________________ | |
116 | void AliUnfolding::SetSkipBinsBegin(Int_t nBins) | |
117 | { | |
118 | // set number of skipped bins in regularization | |
119 | ||
120 | fgSkipBinsBegin = nBins; | |
121 | ||
122 | Printf("AliUnfolding::SetSkipBinsBegin: skipping %d bins at the beginning of the spectrum in the regularization.", fgSkipBinsBegin); | |
123 | } | |
124 | ||
125 | //____________________________________________________________________ | |
126 | void AliUnfolding::SetNbins(Int_t nMeasured, Int_t nUnfolded) | |
127 | { | |
128 | // set number of bins in the input (measured) distribution and in the unfolded distribution | |
129 | fgMaxInput = nMeasured; | |
130 | fgMaxParams = nUnfolded; | |
131 | ||
95e970ca | 132 | if (fgCorrelationMatrix) |
133 | { | |
134 | delete fgCorrelationMatrix; | |
135 | fgCorrelationMatrix = 0; | |
136 | } | |
137 | if (fgCorrelationMatrixSquared) | |
138 | { | |
139 | fgCorrelationMatrixSquared = 0; | |
140 | delete fgCorrelationMatrixSquared; | |
141 | } | |
142 | if (fgCorrelationCovarianceMatrix) | |
143 | { | |
144 | delete fgCorrelationCovarianceMatrix; | |
145 | fgCorrelationCovarianceMatrix = 0; | |
146 | } | |
147 | if (fgCurrentESDVector) | |
148 | { | |
149 | delete fgCurrentESDVector; | |
150 | fgCurrentESDVector = 0; | |
151 | } | |
152 | if (fgEntropyAPriori) | |
153 | { | |
154 | delete fgEntropyAPriori; | |
155 | fgEntropyAPriori = 0; | |
156 | } | |
157 | if (fgEfficiency) | |
158 | { | |
159 | delete fgEfficiency; | |
160 | fgEfficiency = 0; | |
161 | } | |
9e065ad2 | 162 | if (fgUnfoldedAxis) |
163 | { | |
164 | delete fgUnfoldedAxis; | |
165 | fgUnfoldedAxis = 0; | |
166 | } | |
167 | if (fgMeasuredAxis) | |
95e970ca | 168 | { |
9e065ad2 | 169 | delete fgMeasuredAxis; |
170 | fgMeasuredAxis = 0; | |
95e970ca | 171 | } |
172 | ||
19442b86 | 173 | Printf("AliUnfolding::SetNbins: Set %d measured bins and %d unfolded bins", nMeasured, nUnfolded); |
174 | } | |
175 | ||
176 | //____________________________________________________________________ | |
177 | void AliUnfolding::SetChi2Regularization(RegularizationType type, Float_t weight) | |
178 | { | |
179 | // | |
180 | // sets the parameters for chi2 minimization | |
181 | // | |
182 | ||
183 | fgRegularizationType = type; | |
184 | fgRegularizationWeight = weight; | |
185 | ||
186 | Printf("AliUnfolding::SetChi2Regularization --> Regularization set to %d with weight %f", (Int_t) type, weight); | |
187 | } | |
188 | ||
189 | //____________________________________________________________________ | |
190 | void AliUnfolding::SetBayesianParameters(Float_t smoothing, Int_t nIterations) | |
191 | { | |
192 | // | |
193 | // sets the parameters for Bayesian unfolding | |
194 | // | |
195 | ||
196 | fgBayesianSmoothing = smoothing; | |
197 | fgBayesianIterations = nIterations; | |
198 | ||
199 | Printf("AliUnfolding::SetBayesianParameters --> Paramaters set to %d iterations with smoothing %f", fgBayesianIterations, fgBayesianSmoothing); | |
200 | } | |
201 | ||
202 | //____________________________________________________________________ | |
203 | void AliUnfolding::SetFunction(TF1* function) | |
204 | { | |
205 | // set function for unfolding with a fit function | |
206 | ||
207 | fgFitFunction = function; | |
208 | ||
209 | Printf("AliUnfolding::SetFunction: Set fit function with %d parameters.", function->GetNpar()); | |
210 | } | |
211 | ||
212 | //____________________________________________________________________ | |
213 | Int_t AliUnfolding::Unfold(TH2* correlation, TH1* efficiency, TH1* measured, TH1* initialConditions, TH1* result, Bool_t check) | |
214 | { | |
215 | // unfolds with unfolding method fgMethodType | |
216 | // | |
217 | // parameters: | |
218 | // correlation: response matrix as measured vs. generated | |
219 | // efficiency: (optional) efficiency that is applied on the unfolded spectrum, i.e. it has to be in unfolded variables. If 0 no efficiency is applied. | |
220 | // measured: the measured spectrum | |
221 | // initialConditions: (optional) initial conditions for the unfolding. if 0 the measured spectrum is used as initial conditions. | |
222 | // result: target for the unfolded result | |
223 | // check: depends on the unfolding method, see comments in specific functions | |
95e970ca | 224 | // |
225 | // return code: see UnfoldWithMinuit/UnfoldWithBayesian/UnfoldWithFunction | |
19442b86 | 226 | |
227 | if (fgMaxInput == -1) | |
228 | { | |
229 | Printf("AliUnfolding::Unfold: WARNING. Number of measured bins not set with SetNbins. Using number of bins in measured distribution"); | |
230 | fgMaxInput = measured->GetNbinsX(); | |
231 | } | |
232 | if (fgMaxParams == -1) | |
233 | { | |
234 | Printf("AliUnfolding::Unfold: WARNING. Number of unfolded bins not set with SetNbins. Using number of bins in measured distribution"); | |
235 | fgMaxParams = measured->GetNbinsX(); | |
236 | } | |
237 | ||
238 | if (fgOverflowBinLimit > 0) | |
239 | CreateOverflowBin(correlation, measured); | |
240 | ||
241 | switch (fgMethodType) | |
242 | { | |
243 | case kInvalid: | |
244 | { | |
245 | Printf("AliUnfolding::Unfold: ERROR: Unfolding method not set. Use SetUnfoldingMethod. Exiting..."); | |
246 | return -1; | |
247 | } | |
248 | case kChi2Minimization: | |
249 | return UnfoldWithMinuit(correlation, efficiency, measured, initialConditions, result, check); | |
250 | case kBayesian: | |
251 | return UnfoldWithBayesian(correlation, efficiency, measured, initialConditions, result); | |
252 | case kFunction: | |
253 | return UnfoldWithFunction(correlation, efficiency, measured, initialConditions, result); | |
254 | } | |
9e065ad2 | 255 | |
256 | ||
257 | ||
19442b86 | 258 | return -1; |
259 | } | |
260 | ||
261 | //____________________________________________________________________ | |
95e970ca | 262 | void AliUnfolding::SetStaticVariables(TH2* correlation, TH1* measured, TH1* efficiency) |
19442b86 | 263 | { |
264 | // fill static variables needed for minuit fit | |
265 | ||
266 | if (!fgCorrelationMatrix) | |
267 | fgCorrelationMatrix = new TMatrixD(fgMaxInput, fgMaxParams); | |
95e970ca | 268 | if (!fgCorrelationMatrixSquared) |
269 | fgCorrelationMatrixSquared = new TMatrixD(fgMaxInput, fgMaxParams); | |
19442b86 | 270 | if (!fgCorrelationCovarianceMatrix) |
271 | fgCorrelationCovarianceMatrix = new TMatrixD(fgMaxInput, fgMaxInput); | |
272 | if (!fgCurrentESDVector) | |
273 | fgCurrentESDVector = new TVectorD(fgMaxInput); | |
274 | if (!fgEntropyAPriori) | |
275 | fgEntropyAPriori = new TVectorD(fgMaxParams); | |
95e970ca | 276 | if (!fgEfficiency) |
277 | fgEfficiency = new TVectorD(fgMaxParams); | |
9e065ad2 | 278 | if (!fgUnfoldedAxis) |
279 | delete fgUnfoldedAxis; | |
280 | fgUnfoldedAxis = new TAxis(*(correlation->GetXaxis())); | |
281 | if (!fgMeasuredAxis) | |
282 | delete fgMeasuredAxis; | |
283 | fgMeasuredAxis = new TAxis(*(correlation->GetYaxis())); | |
284 | ||
19442b86 | 285 | fgCorrelationMatrix->Zero(); |
286 | fgCorrelationCovarianceMatrix->Zero(); | |
287 | fgCurrentESDVector->Zero(); | |
288 | fgEntropyAPriori->Zero(); | |
289 | ||
290 | // normalize correction for given nPart | |
291 | for (Int_t i=1; i<=correlation->GetNbinsX(); ++i) | |
292 | { | |
293 | Double_t sum = correlation->Integral(i, i, 1, correlation->GetNbinsY()); | |
294 | if (sum <= 0) | |
295 | continue; | |
296 | Float_t maxValue = 0; | |
297 | Int_t maxBin = -1; | |
298 | for (Int_t j=1; j<=correlation->GetNbinsY(); ++j) | |
299 | { | |
300 | // find most probably value | |
301 | if (maxValue < correlation->GetBinContent(i, j)) | |
302 | { | |
303 | maxValue = correlation->GetBinContent(i, j); | |
304 | maxBin = j; | |
305 | } | |
306 | ||
307 | // npart sum to 1 | |
95e970ca | 308 | correlation->SetBinContent(i, j, correlation->GetBinContent(i, j) / sum);// * correlation->GetXaxis()->GetBinWidth(i)); |
19442b86 | 309 | correlation->SetBinError(i, j, correlation->GetBinError(i, j) / sum); |
310 | ||
311 | if (i <= fgMaxParams && j <= fgMaxInput) | |
95e970ca | 312 | { |
19442b86 | 313 | (*fgCorrelationMatrix)(j-1, i-1) = correlation->GetBinContent(i, j); |
95e970ca | 314 | (*fgCorrelationMatrixSquared)(j-1, i-1) = correlation->GetBinContent(i, j) * correlation->GetBinContent(i, j); |
315 | } | |
19442b86 | 316 | } |
317 | ||
318 | //printf("MPV for Ntrue = %f is %f\n", fCurrentCorrelation->GetXaxis()->GetBinCenter(i), fCurrentCorrelation->GetYaxis()->GetBinCenter(maxBin)); | |
319 | } | |
320 | ||
321 | //normalize measured | |
95e970ca | 322 | Float_t smallestError = 1; |
19442b86 | 323 | if (fgNormalizeInput) |
95e970ca | 324 | { |
325 | Float_t sumMeasured = measured->Integral(); | |
326 | measured->Scale(1.0 / sumMeasured); | |
327 | smallestError /= sumMeasured; | |
328 | } | |
19442b86 | 329 | |
330 | for (Int_t i=0; i<fgMaxInput; ++i) | |
331 | { | |
332 | (*fgCurrentESDVector)[i] = measured->GetBinContent(i+1); | |
333 | if (measured->GetBinError(i+1) > 0) | |
95e970ca | 334 | { |
19442b86 | 335 | (*fgCorrelationCovarianceMatrix)(i, i) = (Double_t) 1e-6 / measured->GetBinError(i+1) / measured->GetBinError(i+1); |
95e970ca | 336 | } |
337 | else // in this case put error of 1, otherwise 0 bins are not added to the chi2... | |
338 | (*fgCorrelationCovarianceMatrix)(i, i) = (Double_t) 1e-6 / smallestError / smallestError; | |
19442b86 | 339 | |
340 | if ((*fgCorrelationCovarianceMatrix)(i, i) > 1e7) | |
341 | (*fgCorrelationCovarianceMatrix)(i, i) = 0; | |
342 | //Printf("%d, %e", i, (*fgCorrelationCovarianceMatrix)(i, i)); | |
343 | } | |
95e970ca | 344 | |
345 | // efficiency is expected to match bin width of result | |
346 | for (Int_t i=0; i<fgMaxParams; ++i) | |
347 | { | |
348 | (*fgEfficiency)(i) = efficiency->GetBinContent(i+1); | |
95e970ca | 349 | } |
9e065ad2 | 350 | |
351 | if (correlation->GetNbinsX() != fgMaxParams || correlation->GetNbinsY() != fgMaxInput) | |
352 | cout << "Response histo has incorrect dimensions; expect (" << fgMaxParams << ", " << fgMaxInput << "), got (" << correlation->GetNbinsX() << ", " << correlation->GetNbinsY() << ")" << endl; | |
353 | ||
19442b86 | 354 | } |
355 | ||
356 | //____________________________________________________________________ | |
357 | Int_t AliUnfolding::UnfoldWithMinuit(TH2* correlation, TH1* efficiency, TH1* measured, TH1* initialConditions, TH1* result, Bool_t check) | |
358 | { | |
359 | // | |
360 | // implementation of unfolding (internal function) | |
361 | // | |
362 | // unfolds <measured> using response from <correlation> and effiency <efficiency> | |
363 | // output is in <result> | |
364 | // <initialConditions> set the initial values for the minimization, if 0 <measured> is used | |
95e970ca | 365 | // negative values in initialConditions mean that the given parameter is fixed to the absolute of the value |
19442b86 | 366 | // if <check> is true no unfolding is made, instead only the chi2 without unfolding is printed |
367 | // | |
368 | // returns minuit status (0 = success), (-1 when check was set) | |
369 | // | |
370 | ||
95e970ca | 371 | SetStaticVariables(correlation, measured, efficiency); |
19442b86 | 372 | |
373 | // Initialize TMinuit via generic fitter interface | |
95e970ca | 374 | Int_t params = fgMaxParams; |
375 | if (fgNotFoundEvents > 0) | |
376 | params++; | |
377 | ||
378 | TVirtualFitter *minuit = TVirtualFitter::Fitter(0, params); | |
19442b86 | 379 | Double_t arglist[100]; |
9e065ad2 | 380 | // minuit->SetDefaultFitter("Minuit2"); |
19442b86 | 381 | |
382 | // disable any output (-1), unfortuantly we do not see warnings anymore then. Have to find another way... | |
383 | arglist[0] = 0; | |
384 | minuit->ExecuteCommand("SET PRINT", arglist, 1); | |
385 | ||
386 | // however, enable warnings | |
387 | //minuit->ExecuteCommand("SET WAR", arglist, 0); | |
388 | ||
389 | // set minimization function | |
390 | minuit->SetFCN(Chi2Function); | |
391 | ||
9e065ad2 | 392 | // set precision |
393 | minuit->SetPrecision(fgMinuitPrecision); | |
394 | ||
d22beb7f | 395 | minuit->SetMaxIterations(fgMinuitMaxIterations); |
396 | ||
19442b86 | 397 | for (Int_t i=0; i<fgMaxParams; i++) |
398 | (*fgEntropyAPriori)[i] = 1; | |
399 | ||
95e970ca | 400 | // set initial conditions as a-priori distribution for MRX regularization |
401 | /* | |
402 | for (Int_t i=0; i<fgMaxParams; i++) | |
403 | if (initialConditions && initialConditions->GetBinContent(i+1) > 0) | |
404 | (*fgEntropyAPriori)[i] = initialConditions->GetBinContent(i+1); | |
405 | */ | |
406 | ||
19442b86 | 407 | if (!initialConditions) { |
408 | initialConditions = measured; | |
409 | } else { | |
410 | Printf("AliUnfolding::UnfoldWithMinuit: Using different initial conditions..."); | |
411 | //new TCanvas; initialConditions->DrawCopy(); | |
412 | if (fgNormalizeInput) | |
413 | initialConditions->Scale(1.0 / initialConditions->Integral()); | |
414 | } | |
415 | ||
95e970ca | 416 | // extract minimum value from initial conditions (if we set a value to 0 it will stay 0) |
deaac8b1 | 417 | Float_t minValue = 1e35; |
95e970ca | 418 | if (fgMinimumInitialValueFix < 0) |
419 | { | |
420 | for (Int_t i=0; i<fgMaxParams; ++i) | |
421 | { | |
422 | Int_t bin = initialConditions->GetXaxis()->FindBin(result->GetXaxis()->GetBinCenter(i+1)); | |
423 | if (initialConditions->GetBinContent(bin) > 0) | |
424 | minValue = TMath::Min(minValue, (Float_t) initialConditions->GetBinContent(bin)); | |
425 | } | |
426 | } | |
427 | else | |
428 | minValue = fgMinimumInitialValueFix; | |
429 | ||
19442b86 | 430 | Double_t* results = new Double_t[fgMaxParams+1]; |
431 | for (Int_t i=0; i<fgMaxParams; ++i) | |
432 | { | |
95e970ca | 433 | Int_t bin = initialConditions->GetXaxis()->FindBin(result->GetXaxis()->GetBinCenter(i+1)); |
434 | results[i] = initialConditions->GetBinContent(bin); | |
19442b86 | 435 | |
95e970ca | 436 | Bool_t fix = kFALSE; |
437 | if (results[i] < 0) | |
438 | { | |
439 | fix = kTRUE; | |
440 | results[i] = -results[i]; | |
441 | } | |
442 | ||
443 | if (!fix && fgMinimumInitialValue && results[i] < minValue) | |
444 | results[i] = minValue; | |
445 | ||
19442b86 | 446 | // minuit sees squared values to prevent it from going negative... |
447 | results[i] = TMath::Sqrt(results[i]); | |
448 | ||
95e970ca | 449 | minuit->SetParameter(i, Form("param%d", i), results[i], (fix) ? 0 : fgMinuitStepSize, 0, 0); |
450 | } | |
451 | if (fgNotFoundEvents > 0) | |
452 | { | |
453 | results[fgMaxParams] = efficiency->GetBinContent(1); | |
454 | minuit->SetParameter(fgMaxParams, "vtx0", results[fgMaxParams], fgMinuitStepSize / 100, 0.01, 0.80); | |
19442b86 | 455 | } |
456 | ||
457 | Int_t dummy = 0; | |
458 | Double_t chi2 = 0; | |
459 | Chi2Function(dummy, 0, chi2, results, 0); | |
460 | printf("AliUnfolding::UnfoldWithMinuit: Chi2 of initial parameters is = %f\n", chi2); | |
461 | ||
462 | if (check) | |
463 | { | |
464 | DrawGuess(results); | |
465 | delete[] results; | |
466 | return -1; | |
467 | } | |
468 | ||
469 | // first param is number of iterations, second is precision.... | |
03650114 | 470 | arglist[0] = (float)fgMinuitMaxIterations; |
471 | // arglist[1] = 1e-5; | |
9e065ad2 | 472 | // minuit->ExecuteCommand("SET PRINT", arglist, 3); |
473 | // minuit->ExecuteCommand("SCAN", arglist, 0); | |
19442b86 | 474 | Int_t status = minuit->ExecuteCommand("MIGRAD", arglist, 1); |
475 | Printf("AliUnfolding::UnfoldWithMinuit: MINUIT status is %d", status); | |
476 | //printf("!!!!!!!!!!!!!! MIGRAD finished: Starting MINOS !!!!!!!!!!!!!!"); | |
477 | //minuit->ExecuteCommand("MINOS", arglist, 0); | |
478 | ||
95e970ca | 479 | if (fgNotFoundEvents > 0) |
480 | { | |
481 | results[fgMaxParams] = minuit->GetParameter(fgMaxParams); | |
482 | Printf("Efficiency for bin 0 changed from %f to %f", efficiency->GetBinContent(1), results[fgMaxParams]); | |
483 | efficiency->SetBinContent(1, results[fgMaxParams]); | |
484 | } | |
485 | ||
19442b86 | 486 | for (Int_t i=0; i<fgMaxParams; ++i) |
487 | { | |
488 | results[i] = minuit->GetParameter(i); | |
489 | Double_t value = results[i] * results[i]; | |
a9edd311 | 490 | // error is : 2 * (relError on results[i]) * (value) = 2 * (minuit->GetParError(i) / minuit->GetParameter(i)) * (minuit->GetParameter(i) * minuit->GetParameter(i)) |
b203a518 | 491 | Double_t error = 0; |
492 | if (TMath::IsNaN(minuit->GetParError(i))) | |
493 | Printf("WARNING: Parameter %d error is nan", i); | |
494 | else | |
a9edd311 | 495 | error = 2 * minuit->GetParError(i) * results[i]; |
19442b86 | 496 | |
497 | if (efficiency) | |
95e970ca | 498 | { |
9e065ad2 | 499 | //printf("value before efficiency correction: %f\n",value); |
19442b86 | 500 | if (efficiency->GetBinContent(i+1) > 0) |
501 | { | |
95e970ca | 502 | value /= efficiency->GetBinContent(i+1); |
503 | error /= efficiency->GetBinContent(i+1); | |
19442b86 | 504 | } |
505 | else | |
506 | { | |
95e970ca | 507 | value = 0; |
508 | error = 0; | |
19442b86 | 509 | } |
510 | } | |
9e065ad2 | 511 | //printf("value after efficiency correction: %f +/- %f\n",value,error); |
19442b86 | 512 | result->SetBinContent(i+1, value); |
513 | result->SetBinError(i+1, error); | |
514 | } | |
d22beb7f | 515 | |
516 | Int_t tmpCallCount = fgCallCount; | |
517 | fgCallCount = 0; // needs to be 0 so that the Chi2Function prints its output | |
95e970ca | 518 | Chi2Function(dummy, 0, chi2, results, 0); |
d22beb7f | 519 | |
520 | Printf("AliUnfolding::UnfoldWithMinuit: iterations %d. Chi2 of final parameters is = %f", tmpCallCount, chi2); | |
95e970ca | 521 | |
19442b86 | 522 | delete[] results; |
523 | ||
524 | return status; | |
525 | } | |
526 | ||
527 | //____________________________________________________________________ | |
528 | Int_t AliUnfolding::UnfoldWithBayesian(TH2* correlation, TH1* aEfficiency, TH1* measured, TH1* initialConditions, TH1* aResult) | |
529 | { | |
530 | // | |
531 | // unfolds a spectrum using the Bayesian method | |
532 | // | |
533 | ||
534 | if (measured->Integral() <= 0) | |
535 | { | |
536 | Printf("AliUnfolding::UnfoldWithBayesian: ERROR: The measured spectrum is empty"); | |
537 | return -1; | |
538 | } | |
539 | ||
540 | const Int_t kStartBin = 0; | |
541 | ||
542 | Int_t kMaxM = fgMaxInput; //<= fCurrentCorrelation->GetNbinsY(); // max measured axis | |
543 | Int_t kMaxT = fgMaxParams; //<= fCurrentCorrelation->GetNbinsX(); // max true axis | |
544 | ||
545 | // convergence limit: kMaxT * 0.001^2 = kMaxT * 1e-6 (e.g. 250 bins --> 2.5 e-4) | |
546 | const Double_t kConvergenceLimit = kMaxT * 1e-6; | |
547 | ||
548 | // store information in arrays, to increase processing speed (~ factor 5) | |
549 | Double_t* measuredCopy = new Double_t[kMaxM]; | |
550 | Double_t* measuredError = new Double_t[kMaxM]; | |
551 | Double_t* prior = new Double_t[kMaxT]; | |
552 | Double_t* result = new Double_t[kMaxT]; | |
553 | Double_t* efficiency = new Double_t[kMaxT]; | |
95e970ca | 554 | Double_t* binWidths = new Double_t[kMaxT]; |
19442b86 | 555 | |
556 | Double_t** response = new Double_t*[kMaxT]; | |
557 | Double_t** inverseResponse = new Double_t*[kMaxT]; | |
558 | for (Int_t i=0; i<kMaxT; i++) | |
559 | { | |
560 | response[i] = new Double_t[kMaxM]; | |
561 | inverseResponse[i] = new Double_t[kMaxM]; | |
562 | } | |
563 | ||
564 | // for normalization | |
565 | Float_t measuredIntegral = measured->Integral(); | |
566 | for (Int_t m=0; m<kMaxM; m++) | |
567 | { | |
568 | measuredCopy[m] = measured->GetBinContent(m+1) / measuredIntegral; | |
569 | measuredError[m] = measured->GetBinError(m+1) / measuredIntegral; | |
570 | ||
571 | for (Int_t t=0; t<kMaxT; t++) | |
572 | { | |
573 | response[t][m] = correlation->GetBinContent(t+1, m+1); | |
574 | inverseResponse[t][m] = 0; | |
575 | } | |
576 | } | |
577 | ||
578 | for (Int_t t=0; t<kMaxT; t++) | |
579 | { | |
651e2088 | 580 | if (aEfficiency) |
19442b86 | 581 | { |
582 | efficiency[t] = aEfficiency->GetBinContent(t+1); | |
583 | } | |
584 | else | |
585 | efficiency[t] = 1; | |
586 | ||
587 | prior[t] = measuredCopy[t]; | |
588 | result[t] = 0; | |
95e970ca | 589 | binWidths[t] = aResult->GetXaxis()->GetBinWidth(t+1); |
19442b86 | 590 | } |
591 | ||
592 | // pick prior distribution | |
593 | if (initialConditions) | |
594 | { | |
595 | printf("Using different starting conditions...\n"); | |
596 | // for normalization | |
597 | Float_t inputDistIntegral = initialConditions->Integral(); | |
598 | for (Int_t i=0; i<kMaxT; i++) | |
599 | prior[i] = initialConditions->GetBinContent(i+1) / inputDistIntegral; | |
600 | } | |
601 | ||
602 | //TH1F* convergence = new TH1F("convergence", "convergence", 200, 0.5, 200.5); | |
603 | ||
95e970ca | 604 | //new TCanvas; |
19442b86 | 605 | // unfold... |
95e970ca | 606 | for (Int_t i=0; i<fgBayesianIterations || fgBayesianIterations < 0; i++) |
19442b86 | 607 | { |
608 | if (fgDebug) | |
609 | Printf("AliUnfolding::UnfoldWithBayesian: iteration %i", i); | |
610 | ||
95e970ca | 611 | // calculate IR from Bayes theorem |
19442b86 | 612 | // IR_ji = R_ij * prior_i / sum_k(R_kj * prior_k) |
613 | ||
614 | Double_t chi2Measured = 0; | |
615 | for (Int_t m=0; m<kMaxM; m++) | |
616 | { | |
617 | Float_t norm = 0; | |
618 | for (Int_t t = kStartBin; t<kMaxT; t++) | |
619 | norm += response[t][m] * prior[t]; | |
620 | ||
621 | // calc. chi2: (measured - response * prior) / error | |
622 | if (measuredError[m] > 0) | |
623 | { | |
624 | Double_t value = (measuredCopy[m] - norm) / measuredError[m]; | |
625 | chi2Measured += value * value; | |
626 | } | |
627 | ||
628 | if (norm > 0) | |
629 | { | |
630 | for (Int_t t = kStartBin; t<kMaxT; t++) | |
631 | inverseResponse[t][m] = response[t][m] * prior[t] / norm; | |
632 | } | |
633 | else | |
634 | { | |
635 | for (Int_t t = kStartBin; t<kMaxT; t++) | |
636 | inverseResponse[t][m] = 0; | |
637 | } | |
638 | } | |
639 | //Printf("chi2Measured of the last prior is %e", chi2Measured); | |
640 | ||
641 | for (Int_t t = kStartBin; t<kMaxT; t++) | |
642 | { | |
643 | Float_t value = 0; | |
644 | for (Int_t m=0; m<kMaxM; m++) | |
645 | value += inverseResponse[t][m] * measuredCopy[m]; | |
646 | ||
647 | if (efficiency[t] > 0) | |
648 | result[t] = value / efficiency[t]; | |
649 | else | |
650 | result[t] = 0; | |
651 | } | |
652 | ||
95e970ca | 653 | /* |
19442b86 | 654 | // draw intermediate result |
19442b86 | 655 | for (Int_t t=0; t<kMaxT; t++) |
95e970ca | 656 | { |
19442b86 | 657 | aResult->SetBinContent(t+1, result[t]); |
95e970ca | 658 | } |
659 | aResult->SetMarkerStyle(24+i); | |
19442b86 | 660 | aResult->SetMarkerColor(2); |
95e970ca | 661 | aResult->DrawCopy((i == 0) ? "P" : "PSAME"); |
19442b86 | 662 | */ |
95e970ca | 663 | |
19442b86 | 664 | Double_t chi2LastIter = 0; |
665 | // regularization (simple smoothing) | |
666 | for (Int_t t=kStartBin; t<kMaxT; t++) | |
667 | { | |
668 | Float_t newValue = 0; | |
669 | ||
670 | // 0 bin excluded from smoothing | |
671 | if (t > kStartBin+2 && t<kMaxT-1) | |
672 | { | |
95e970ca | 673 | Float_t average = (result[t-1] / binWidths[t-1] + result[t] / binWidths[t] + result[t+1] / binWidths[t+1]) / 3 * binWidths[t]; |
19442b86 | 674 | |
675 | // weight the average with the regularization parameter | |
676 | newValue = (1 - fgBayesianSmoothing) * result[t] + fgBayesianSmoothing * average; | |
677 | } | |
678 | else | |
679 | newValue = result[t]; | |
680 | ||
681 | // calculate chi2 (change from last iteration) | |
682 | if (prior[t] > 1e-5) | |
683 | { | |
684 | Double_t diff = (prior[t] - newValue) / prior[t]; | |
685 | chi2LastIter += diff * diff; | |
686 | } | |
687 | ||
688 | prior[t] = newValue; | |
689 | } | |
690 | //printf("Chi2 of %d iteration = %e\n", i, chi2LastIter); | |
691 | //convergence->Fill(i+1, chi2LastIter); | |
692 | ||
693 | if (fgBayesianIterations < 0 && chi2LastIter < kConvergenceLimit) | |
694 | { | |
695 | Printf("AliUnfolding::UnfoldWithBayesian: Stopped Bayesian unfolding after %d iterations at chi2(change since last iteration) of %e; chi2Measured of the last prior is %e", i, chi2LastIter, chi2Measured); | |
696 | break; | |
697 | } | |
698 | } // end of iterations | |
699 | ||
700 | //new TCanvas; convergence->DrawCopy(); gPad->SetLogy(); | |
701 | //delete convergence; | |
702 | ||
95e970ca | 703 | Float_t factor = 1; |
704 | if (!fgNormalizeInput) | |
705 | factor = measuredIntegral; | |
19442b86 | 706 | for (Int_t t=0; t<kMaxT; t++) |
95e970ca | 707 | aResult->SetBinContent(t+1, result[t] * factor); |
19442b86 | 708 | |
709 | delete[] measuredCopy; | |
710 | delete[] measuredError; | |
711 | delete[] prior; | |
712 | delete[] result; | |
713 | delete[] efficiency; | |
95e970ca | 714 | delete[] binWidths; |
19442b86 | 715 | |
716 | for (Int_t i=0; i<kMaxT; i++) | |
717 | { | |
718 | delete[] response[i]; | |
719 | delete[] inverseResponse[i]; | |
720 | } | |
721 | delete[] response; | |
722 | delete[] inverseResponse; | |
723 | ||
724 | return 0; | |
725 | ||
726 | // ******** | |
727 | // Calculate the covariance matrix, all arguments are taken from NIM,A362,487-498,1995 | |
728 | ||
729 | /*printf("Calculating covariance matrix. This may take some time...\n"); | |
730 | ||
731 | // check if this is the right one... | |
732 | TH1* sumHist = GetMultiplicityMC(inputRange, eventType)->ProjectionY("sumHist", 1, GetMultiplicityMC(inputRange, eventType)->GetNbinsX()); | |
733 | ||
734 | Int_t xBins = hInverseResponseBayes->GetNbinsX(); | |
735 | Int_t yBins = hInverseResponseBayes->GetNbinsY(); | |
736 | ||
737 | // calculate "unfolding matrix" Mij | |
738 | Float_t matrixM[251][251]; | |
739 | for (Int_t i=1; i<=xBins; i++) | |
740 | { | |
741 | for (Int_t j=1; j<=yBins; j++) | |
742 | { | |
743 | if (fCurrentEfficiency->GetBinContent(i) > 0) | |
744 | matrixM[i-1][j-1] = hInverseResponseBayes->GetBinContent(i, j) / fCurrentEfficiency->GetBinContent(i); | |
745 | else | |
746 | matrixM[i-1][j-1] = 0; | |
747 | } | |
748 | } | |
749 | ||
750 | Float_t* vectorn = new Float_t[yBins]; | |
751 | for (Int_t j=1; j<=yBins; j++) | |
752 | vectorn[j-1] = fCurrentESD->GetBinContent(j); | |
753 | ||
754 | // first part of covariance matrix, depends on input distribution n(E) | |
755 | Float_t cov1[251][251]; | |
756 | ||
757 | Float_t nEvents = fCurrentESD->Integral(); // N | |
758 | ||
759 | xBins = 20; | |
760 | yBins = 20; | |
761 | ||
762 | for (Int_t k=0; k<xBins; k++) | |
763 | { | |
764 | printf("In Cov1: %d\n", k); | |
765 | for (Int_t l=0; l<yBins; l++) | |
766 | { | |
767 | cov1[k][l] = 0; | |
768 | ||
769 | // sum_j Mkj Mlj n(Ej) * (1 - n(Ej) / N) | |
770 | for (Int_t j=0; j<yBins; j++) | |
771 | cov1[k][l] += matrixM[k][j] * matrixM[l][j] * vectorn[j] | |
772 | * (1.0 - vectorn[j] / nEvents); | |
773 | ||
774 | // - sum_i,j (i != j) Mki Mlj n(Ei) n(Ej) / N | |
775 | for (Int_t i=0; i<yBins; i++) | |
776 | for (Int_t j=0; j<yBins; j++) | |
777 | { | |
778 | if (i == j) | |
779 | continue; | |
780 | cov1[k][l] -= matrixM[k][i] * matrixM[l][j] * vectorn[i] | |
781 | * vectorn[j] / nEvents; | |
782 | } | |
783 | } | |
784 | } | |
785 | ||
786 | printf("Cov1 finished\n"); | |
787 | ||
788 | TH2F* cov = (TH2F*) hInverseResponseBayes->Clone("cov"); | |
789 | cov->Reset(); | |
790 | ||
791 | for (Int_t i=1; i<=xBins; i++) | |
792 | for (Int_t j=1; j<=yBins; j++) | |
793 | cov->SetBinContent(i, j, cov1[i-1][j-1]); | |
794 | ||
795 | new TCanvas; | |
796 | cov->Draw("COLZ"); | |
797 | ||
798 | // second part of covariance matrix, depends on response matrix | |
799 | Float_t cov2[251][251]; | |
800 | ||
801 | // Cov[P(Er|Cu), P(Es|Cu)] term | |
802 | Float_t covTerm[100][100][100]; | |
803 | for (Int_t r=0; r<yBins; r++) | |
804 | for (Int_t u=0; u<xBins; u++) | |
805 | for (Int_t s=0; s<yBins; s++) | |
806 | { | |
807 | if (r == s) | |
808 | covTerm[r][u][s] = 1.0 / sumHist->GetBinContent(u+1) * hResponse->GetBinContent(u+1, r+1) | |
809 | * (1.0 - hResponse->GetBinContent(u+1, r+1)); | |
810 | else | |
811 | covTerm[r][u][s] = - 1.0 / sumHist->GetBinContent(u+1) * hResponse->GetBinContent(u+1, r+1) | |
812 | * hResponse->GetBinContent(u+1, s+1); | |
813 | } | |
814 | ||
815 | for (Int_t k=0; k<xBins; k++) | |
816 | for (Int_t l=0; l<yBins; l++) | |
817 | { | |
818 | cov2[k][l] = 0; | |
819 | printf("In Cov2: %d %d\n", k, l); | |
820 | for (Int_t i=0; i<yBins; i++) | |
821 | for (Int_t j=0; j<yBins; j++) | |
822 | { | |
823 | //printf("In Cov2: %d %d %d %d\n", k, l, i, j); | |
824 | // calculate Cov(Mki, Mlj) = sum{ru},{su} ... | |
825 | Float_t tmpCov = 0; | |
826 | for (Int_t r=0; r<yBins; r++) | |
827 | for (Int_t u=0; u<xBins; u++) | |
828 | for (Int_t s=0; s<yBins; s++) | |
829 | { | |
830 | if (hResponse->GetBinContent(u+1, r+1) == 0 || hResponse->GetBinContent(u+1, s+1) == 0 | |
831 | || hResponse->GetBinContent(u+1, i+1) == 0) | |
832 | continue; | |
833 | ||
834 | tmpCov += BayesCovarianceDerivate(matrixM, hResponse, fCurrentEfficiency, k, i, r, u) | |
835 | * BayesCovarianceDerivate(matrixM, hResponse, fCurrentEfficiency, l, j, s, u) | |
836 | * covTerm[r][u][s]; | |
837 | } | |
838 | ||
839 | cov2[k][l] += fCurrentESD->GetBinContent(i+1) * fCurrentESD->GetBinContent(j+1) * tmpCov; | |
840 | } | |
841 | } | |
842 | ||
843 | printf("Cov2 finished\n"); | |
844 | ||
845 | for (Int_t i=1; i<=xBins; i++) | |
846 | for (Int_t j=1; j<=yBins; j++) | |
847 | cov->SetBinContent(i, j, cov1[i-1][j-1] + cov2[i-1][j-1]); | |
848 | ||
849 | new TCanvas; | |
850 | cov->Draw("COLZ");*/ | |
851 | } | |
852 | ||
853 | //____________________________________________________________________ | |
854 | Double_t AliUnfolding::RegularizationPol0(TVectorD& params) | |
855 | { | |
856 | // homogenity term for minuit fitting | |
857 | // pure function of the parameters | |
858 | // prefers constant function (pol0) | |
9e065ad2 | 859 | // |
860 | // Does not take into account efficiency | |
19442b86 | 861 | Double_t chi2 = 0; |
862 | ||
863 | for (Int_t i=1+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
864 | { | |
9e065ad2 | 865 | Double_t right = params[i] / fgUnfoldedAxis->GetBinWidth(i+1); |
866 | Double_t left = params[i-1] / fgUnfoldedAxis->GetBinWidth(i); | |
19442b86 | 867 | |
95e970ca | 868 | if (left != 0) |
19442b86 | 869 | { |
95e970ca | 870 | Double_t diff = (right - left); |
9e065ad2 | 871 | chi2 += diff * diff / left / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); |
19442b86 | 872 | } |
873 | } | |
874 | ||
875 | return chi2 / 100.0; | |
876 | } | |
877 | ||
878 | //____________________________________________________________________ | |
879 | Double_t AliUnfolding::RegularizationPol1(TVectorD& params) | |
880 | { | |
881 | // homogenity term for minuit fitting | |
882 | // pure function of the parameters | |
883 | // prefers linear function (pol1) | |
9e065ad2 | 884 | // |
885 | // Does not take into account efficiency | |
19442b86 | 886 | Double_t chi2 = 0; |
887 | ||
888 | for (Int_t i=2+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
889 | { | |
890 | if (params[i-1] == 0) | |
891 | continue; | |
892 | ||
9e065ad2 | 893 | Double_t right = params[i] / fgUnfoldedAxis->GetBinWidth(i+1); |
894 | Double_t middle = params[i-1] / fgUnfoldedAxis->GetBinWidth(i); | |
895 | Double_t left = params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1); | |
19442b86 | 896 | |
9e065ad2 | 897 | Double_t der1 = (right - middle) / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); |
898 | Double_t der2 = (middle - left) / ((fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i-1)) / 2); | |
19442b86 | 899 | |
95e970ca | 900 | //Double_t diff = (der1 - der2) / middle; |
901 | //chi2 += diff * diff; | |
9e065ad2 | 902 | chi2 += (der1 - der2) * (der1 - der2) / middle * fgUnfoldedAxis->GetBinWidth(i); |
19442b86 | 903 | } |
904 | ||
905 | return chi2; | |
906 | } | |
907 | ||
908 | //____________________________________________________________________ | |
909 | Double_t AliUnfolding::RegularizationLog(TVectorD& params) | |
910 | { | |
911 | // homogenity term for minuit fitting | |
912 | // pure function of the parameters | |
9e065ad2 | 913 | // prefers logarithmic function (log) |
914 | // | |
915 | // Does not take into account efficiency | |
19442b86 | 916 | |
917 | Double_t chi2 = 0; | |
918 | ||
919 | for (Int_t i=2+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
920 | { | |
95e970ca | 921 | if (params[i-1] == 0 || params[i] == 0 || params[i-2] == 0) |
922 | continue; | |
19442b86 | 923 | |
9e065ad2 | 924 | Double_t right = log(params[i] / fgUnfoldedAxis->GetBinWidth(i+1)); |
925 | Double_t middle = log(params[i-1] / fgUnfoldedAxis->GetBinWidth(i)); | |
926 | Double_t left = log(params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1)); | |
95e970ca | 927 | |
9e065ad2 | 928 | Double_t der1 = (right - middle) / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); |
929 | Double_t der2 = (middle - left) / ((fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i-1)) / 2); | |
95e970ca | 930 | |
931 | //Double_t error = 1. / params[i] + 4. / params[i-1] + 1. / params[i-2]; | |
19442b86 | 932 | |
95e970ca | 933 | //if (fgCallCount == 0) |
934 | // Printf("%d %f %f", i, (der1 - der2) * (der1 - der2), error); | |
935 | chi2 += (der1 - der2) * (der1 - der2);// / error; | |
19442b86 | 936 | } |
937 | ||
95e970ca | 938 | return chi2; |
19442b86 | 939 | } |
940 | ||
941 | //____________________________________________________________________ | |
942 | Double_t AliUnfolding::RegularizationTotalCurvature(TVectorD& params) | |
943 | { | |
944 | // homogenity term for minuit fitting | |
945 | // pure function of the parameters | |
946 | // minimizes the total curvature (from Unfolding Methods In High-Energy Physics Experiments, | |
947 | // V. Blobel (Hamburg U.) . DESY 84/118, Dec 1984. 40pp. | |
9e065ad2 | 948 | // |
949 | // Does not take into account efficiency | |
19442b86 | 950 | |
951 | Double_t chi2 = 0; | |
952 | ||
953 | for (Int_t i=2+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
954 | { | |
955 | Double_t right = params[i]; | |
956 | Double_t middle = params[i-1]; | |
957 | Double_t left = params[i-2]; | |
958 | ||
959 | Double_t der1 = (right - middle); | |
960 | Double_t der2 = (middle - left); | |
961 | ||
962 | Double_t diff = (der1 - der2); | |
963 | ||
964 | chi2 += diff * diff; | |
965 | } | |
966 | ||
967 | return chi2 * 1e4; | |
968 | } | |
969 | ||
970 | //____________________________________________________________________ | |
971 | Double_t AliUnfolding::RegularizationEntropy(TVectorD& params) | |
972 | { | |
973 | // homogenity term for minuit fitting | |
974 | // pure function of the parameters | |
975 | // calculates entropy, from | |
976 | // The method of reduced cross-entropy (M. Schmelling 1993) | |
9e065ad2 | 977 | // |
978 | // Does not take into account efficiency | |
19442b86 | 979 | |
980 | Double_t paramSum = 0; | |
981 | ||
982 | for (Int_t i=fgSkipBinsBegin; i<fgMaxParams; ++i) | |
983 | paramSum += params[i]; | |
984 | ||
985 | Double_t chi2 = 0; | |
986 | for (Int_t i=fgSkipBinsBegin; i<fgMaxParams; ++i) | |
987 | { | |
95e970ca | 988 | Double_t tmp = params[i] / paramSum; |
989 | //Double_t tmp = params[i]; | |
19442b86 | 990 | if (tmp > 0 && (*fgEntropyAPriori)[i] > 0) |
991 | { | |
992 | chi2 += tmp * TMath::Log(tmp / (*fgEntropyAPriori)[i]); | |
993 | } | |
95e970ca | 994 | else |
995 | chi2 += 100; | |
996 | } | |
997 | ||
998 | return -chi2; | |
999 | } | |
1000 | ||
1001 | //____________________________________________________________________ | |
1002 | Double_t AliUnfolding::RegularizationRatio(TVectorD& params) | |
1003 | { | |
1004 | // homogenity term for minuit fitting | |
1005 | // pure function of the parameters | |
9e065ad2 | 1006 | // |
1007 | // Does not take into account efficiency | |
95e970ca | 1008 | |
1009 | Double_t chi2 = 0; | |
1010 | ||
1011 | for (Int_t i=5+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
1012 | { | |
1013 | if (params[i-1] == 0 || params[i] == 0) | |
1014 | continue; | |
1015 | ||
9e065ad2 | 1016 | Double_t right = params[i] / fgUnfoldedAxis->GetBinWidth(i+1); |
1017 | Double_t middle = params[i-1] / fgUnfoldedAxis->GetBinWidth(i); | |
1018 | Double_t left = params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1); | |
1019 | Double_t left2 = params[i-3] / fgUnfoldedAxis->GetBinWidth(i-2); | |
1020 | Double_t left3 = params[i-4] / fgUnfoldedAxis->GetBinWidth(i-3); | |
1021 | Double_t left4 = params[i-5] / fgUnfoldedAxis->GetBinWidth(i-4); | |
95e970ca | 1022 | |
1023 | //Double_t diff = left / middle - middle / right; | |
1024 | //Double_t diff = 2 * left / middle - middle / right - left2 / left; | |
1025 | Double_t diff = 4 * left2 / left - middle / right - left / middle - left3 / left2 - left4 / left3; | |
1026 | ||
1027 | chi2 += diff * diff;// / middle; | |
19442b86 | 1028 | } |
1029 | ||
95e970ca | 1030 | return chi2; |
19442b86 | 1031 | } |
1032 | ||
9e065ad2 | 1033 | //____________________________________________________________________ |
1034 | Double_t AliUnfolding::RegularizationPowerLaw(TVectorD& params) | |
1035 | { | |
1036 | // homogenity term for minuit fitting | |
1037 | // pure function of the parameters | |
1038 | // prefers power law with n = -5 | |
1039 | // | |
1040 | // Does not take into account efficiency | |
1041 | ||
1042 | Double_t chi2 = 0; | |
1043 | ||
1044 | Double_t right = 0.; | |
1045 | Double_t middle = 0.; | |
1046 | Double_t left = 0.; | |
1047 | ||
1048 | for (Int_t i=2+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
1049 | { | |
1050 | if (params[i] < 1e-8 || params[i-1] < 1e-8 || params[i-2] < 1e-8) | |
1051 | continue; | |
1052 | ||
1053 | if (fgUnfoldedAxis->GetBinWidth(i+1) < 1e-8 || fgUnfoldedAxis->GetBinWidth(i) < 1e-8 || fgUnfoldedAxis->GetBinWidth(i-1) < 1e-8) | |
1054 | continue; | |
1055 | ||
1056 | middle = TMath::Power(params[i-1] / fgUnfoldedAxis->GetBinWidth(i),fgPowern); | |
1057 | ||
1058 | if(middle>0) { | |
1059 | right = TMath::Power(params[i] / fgUnfoldedAxis->GetBinWidth(i),fgPowern)/middle; | |
1060 | ||
1061 | left = TMath::Power(params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1),fgPowern)/middle; | |
1062 | ||
1063 | middle = 1.; | |
1064 | ||
1065 | Double_t der1 = (right - middle) / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); | |
1066 | Double_t der2 = (middle - left) / ((fgUnfoldedAxis->GetBinWidth(i-1) + fgUnfoldedAxis->GetBinWidth(i-2)) / 2); | |
1067 | ||
1068 | chi2 += (der1 - der2) * (der1 - der2)/ ( fgUnfoldedAxis->GetBinWidth(i)/2. + fgUnfoldedAxis->GetBinWidth(i-1) + fgUnfoldedAxis->GetBinWidth(i-2)/2.)/( fgUnfoldedAxis->GetBinWidth(i)/2. + fgUnfoldedAxis->GetBinWidth(i-1) + fgUnfoldedAxis->GetBinWidth(i-2)/2.);// / error; | |
1069 | // printf("i: %d chi2 = %f\n",i,chi2); | |
1070 | } | |
1071 | ||
1072 | } | |
1073 | ||
1074 | return chi2; | |
1075 | } | |
1076 | ||
1077 | //____________________________________________________________________ | |
1078 | Double_t AliUnfolding::RegularizationLogLog(TVectorD& params) | |
1079 | { | |
1080 | // homogenity term for minuit fitting | |
1081 | // pure function of the parameters | |
1082 | // prefers a powerlaw (linear on a log-log scale) | |
1083 | // | |
1084 | // The calculation takes into account the efficiencies | |
1085 | ||
1086 | Double_t chi2 = 0; | |
1087 | ||
1088 | for (Int_t i=2+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
1089 | { | |
1090 | if (params[i-1] == 0 || params[i] == 0 || params[i-2] == 0) | |
1091 | continue; | |
1092 | if ((*fgEfficiency)(i-1) == 0 || (*fgEfficiency)(i) == 0 || (*fgEfficiency)(i-2) == 0) | |
1093 | continue; | |
1094 | ||
1095 | ||
1096 | Double_t right = log(params[i] / (*fgEfficiency)(i) / fgUnfoldedAxis->GetBinWidth(i)); | |
1097 | Double_t middle = log(params[i-1] / (*fgEfficiency)(i-1) / fgUnfoldedAxis->GetBinWidth(i-1)); | |
1098 | Double_t left = log(params[i-2] / (*fgEfficiency)(i-2) / fgUnfoldedAxis->GetBinWidth(i-2)); | |
1099 | ||
1100 | Double_t der1 = (right - middle) / ( log(fgUnfoldedAxis->GetBinCenter(i+1)) - log(fgUnfoldedAxis->GetBinCenter(i)) ); | |
1101 | Double_t der2 = (middle - left) /( log(fgUnfoldedAxis->GetBinCenter(i)) - log(fgUnfoldedAxis->GetBinCenter(i-1)) ); | |
1102 | ||
1103 | double tmp = (log(fgUnfoldedAxis->GetBinCenter(i+1)) - log(fgUnfoldedAxis->GetBinCenter(i-1)))/2.; | |
1104 | Double_t dder = (der1-der2) / tmp; | |
1105 | ||
1106 | chi2 += dder * dder; | |
1107 | } | |
1108 | ||
1109 | return chi2; | |
1110 | } | |
1111 | ||
1112 | ||
1113 | ||
19442b86 | 1114 | //____________________________________________________________________ |
1115 | void AliUnfolding::Chi2Function(Int_t&, Double_t*, Double_t& chi2, Double_t *params, Int_t) | |
1116 | { | |
1117 | // | |
1118 | // fit function for minuit | |
1119 | // does: (m - Ad)W(m - Ad) where m = measured, A correlation matrix, d = guess, W = covariance matrix | |
1120 | // | |
95e970ca | 1121 | |
1122 | // TODO use static members for the variables here to speed up processing (no construction/deconstruction) | |
19442b86 | 1123 | |
9e065ad2 | 1124 | // d = guess |
95e970ca | 1125 | TVectorD paramsVector(fgMaxParams); |
19442b86 | 1126 | for (Int_t i=0; i<fgMaxParams; ++i) |
1127 | paramsVector[i] = params[i] * params[i]; | |
1128 | ||
1129 | // calculate penalty factor | |
1130 | Double_t penaltyVal = 0; | |
9e065ad2 | 1131 | |
19442b86 | 1132 | switch (fgRegularizationType) |
1133 | { | |
1134 | case kNone: break; | |
1135 | case kPol0: penaltyVal = RegularizationPol0(paramsVector); break; | |
1136 | case kPol1: penaltyVal = RegularizationPol1(paramsVector); break; | |
1137 | case kCurvature: penaltyVal = RegularizationTotalCurvature(paramsVector); break; | |
1138 | case kEntropy: penaltyVal = RegularizationEntropy(paramsVector); break; | |
1139 | case kLog: penaltyVal = RegularizationLog(paramsVector); break; | |
95e970ca | 1140 | case kRatio: penaltyVal = RegularizationRatio(paramsVector); break; |
9e065ad2 | 1141 | case kPowerLaw: penaltyVal = RegularizationPowerLaw(paramsVector); break; |
1142 | case kLogLog: penaltyVal = RegularizationLogLog(paramsVector); break; | |
19442b86 | 1143 | } |
1144 | ||
9e065ad2 | 1145 | penaltyVal *= fgRegularizationWeight; //beta*PU |
19442b86 | 1146 | |
1147 | // Ad | |
1148 | TVectorD measGuessVector(fgMaxInput); | |
1149 | measGuessVector = (*fgCorrelationMatrix) * paramsVector; | |
1150 | ||
1151 | // Ad - m | |
1152 | measGuessVector -= (*fgCurrentESDVector); | |
95e970ca | 1153 | |
1154 | #if 0 | |
1155 | // new error calcuation using error on the guess | |
1156 | ||
1157 | // error from guess | |
1158 | TVectorD errorGuessVector(fgMaxInput); | |
1159 | //errorGuessVector = (*fgCorrelationMatrixSquared) * paramsVector; | |
1160 | errorGuessVector = (*fgCorrelationMatrix) * paramsVector; | |
19442b86 | 1161 | |
95e970ca | 1162 | Double_t chi2FromFit = 0; |
1163 | for (Int_t i=0; i<fgMaxInput; ++i) | |
1164 | { | |
1165 | Float_t error = 1; | |
1166 | if (errorGuessVector(i) > 0) | |
1167 | error = errorGuessVector(i); | |
1168 | chi2FromFit += measGuessVector(i) * measGuessVector(i) / error; | |
1169 | } | |
19442b86 | 1170 | |
95e970ca | 1171 | #else |
1172 | // old error calcuation using the error on the measured | |
19442b86 | 1173 | TVectorD copy(measGuessVector); |
1174 | ||
1175 | // (Ad - m) W | |
1176 | // this step can be optimized because currently only the diagonal elements of fgCorrelationCovarianceMatrix are used | |
1177 | // normal way is like this: | |
1178 | // measGuessVector *= (*fgCorrelationCovarianceMatrix); | |
1179 | // optimized way like this: | |
1180 | for (Int_t i=0; i<fgMaxInput; ++i) | |
1181 | measGuessVector[i] *= (*fgCorrelationCovarianceMatrix)(i, i); | |
1182 | ||
19442b86 | 1183 | |
95e970ca | 1184 | if (fgSkipBin0InChi2) |
1185 | measGuessVector[0] = 0; | |
1186 | ||
19442b86 | 1187 | // (Ad - m) W (Ad - m) |
1188 | // the factor 1e6 prevents that a very small number (measGuessVector[i]) is multiplied with a very | |
95e970ca | 1189 | // big number ((*fgCorrelationCovarianceMatrix)(i, i)) (see UnfoldWithMinuit) |
19442b86 | 1190 | Double_t chi2FromFit = measGuessVector * copy * 1e6; |
95e970ca | 1191 | #endif |
19442b86 | 1192 | |
95e970ca | 1193 | Double_t notFoundEventsConstraint = 0; |
1194 | Double_t currentNotFoundEvents = 0; | |
1195 | Double_t errorNotFoundEvents = 0; | |
1196 | ||
1197 | if (fgNotFoundEvents > 0) | |
1198 | { | |
1199 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1200 | { | |
1201 | Double_t eff = (1.0 / (*fgEfficiency)(i) - 1); | |
1202 | if (i == 0) | |
1203 | eff = (1.0 / params[fgMaxParams] - 1); | |
1204 | currentNotFoundEvents += eff * paramsVector(i); | |
1205 | errorNotFoundEvents += eff * eff * paramsVector(i); // error due to guess (paramsVector) | |
1206 | if (i <= 3) | |
1207 | errorNotFoundEvents += (eff * 0.03) * (eff * 0.03) * paramsVector(i) * paramsVector(i); // error on eff | |
9e065ad2 | 1208 | // if ((fgCallCount % 10000) == 0) |
1209 | //Printf("%d %f %f %f", i, (*fgEfficiency)(i), paramsVector(i), currentNotFoundEvents); | |
95e970ca | 1210 | } |
1211 | errorNotFoundEvents += fgNotFoundEvents; | |
1212 | // TODO add error on background, background estimate | |
1213 | ||
1214 | notFoundEventsConstraint = (currentNotFoundEvents - fgNotFoundEvents) * (currentNotFoundEvents - fgNotFoundEvents) / errorNotFoundEvents; | |
1215 | } | |
1216 | ||
1217 | Float_t avg = 0; | |
1218 | Float_t sum = 0; | |
1219 | Float_t currentMult = 0; | |
1220 | // try to match dn/deta | |
1221 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1222 | { | |
1223 | avg += paramsVector(i) * currentMult; | |
1224 | sum += paramsVector(i); | |
9e065ad2 | 1225 | currentMult += fgUnfoldedAxis->GetBinWidth(i); |
95e970ca | 1226 | } |
1227 | avg /= sum; | |
1228 | Float_t chi2Avg = 0; //(avg - 3.73) * (avg - 3.73) * 100; | |
19442b86 | 1229 | |
95e970ca | 1230 | chi2 = chi2FromFit + penaltyVal + notFoundEventsConstraint + chi2Avg; |
9e065ad2 | 1231 | |
95e970ca | 1232 | if ((fgCallCount++ % 1000) == 0) |
1233 | { | |
9e065ad2 | 1234 | |
1235 | Printf("AliUnfolding::Chi2Function: Iteration %d (ev %d %d +- %f) (%f) (%f): %f %f %f %f --> %f", fgCallCount-1, (Int_t) fgNotFoundEvents, (Int_t) currentNotFoundEvents, TMath::Sqrt(errorNotFoundEvents), params[fgMaxParams-1], avg, chi2FromFit, penaltyVal, notFoundEventsConstraint, chi2Avg, chi2); | |
1236 | ||
95e970ca | 1237 | //for (Int_t i=0; i<fgMaxInput; ++i) |
1238 | // Printf("%d: %f", i, measGuessVector(i) * copy(i) * 1e6); | |
1239 | } | |
9e065ad2 | 1240 | |
1241 | fChi2FromFit = chi2FromFit; | |
1242 | fPenaltyVal = penaltyVal; | |
19442b86 | 1243 | } |
1244 | ||
1245 | //____________________________________________________________________ | |
9e065ad2 | 1246 | void AliUnfolding::MakePads() { |
1247 | TPad *presult = new TPad("presult","result",0,0.4,1,1); | |
1248 | presult->SetNumber(1); | |
1249 | presult->Draw(); | |
1250 | presult->SetLogy(); | |
1251 | TPad *pres = new TPad("pres","residuals",0,0.2,1,0.4); | |
1252 | pres->SetNumber(2); | |
1253 | pres->Draw(); | |
1254 | TPad *ppen = new TPad("ppen","penalty",0,0.0,1,0.2); | |
1255 | ppen->SetNumber(3); | |
1256 | ppen->Draw(); | |
1257 | ||
1258 | } | |
1259 | //____________________________________________________________________ | |
1260 | void AliUnfolding::DrawResults(TH2* correlation, TH1* efficiency, TH1* measured, TH1* initialConditions, TCanvas *canv, Int_t reuseHists,TH1 *unfolded) | |
1261 | { | |
1262 | // Draw histograms of | |
1263 | // - Result folded with response | |
1264 | // - Penalty factors | |
1265 | // - Chisquare contributions | |
1266 | // (Useful for debugging/sanity checks and the interactive unfolder) | |
1267 | // | |
1268 | // If a canvas pointer is given (canv != 0), it will be used for all | |
1269 | // plots; 3 pads are made if needed. | |
1270 | ||
1271 | ||
1272 | Int_t blankCanvas = 0; | |
1273 | TVirtualPad *presult = 0; | |
1274 | TVirtualPad *pres = 0; | |
1275 | TVirtualPad *ppen = 0; | |
1276 | ||
1277 | if (canv) { | |
1278 | canv->cd(); | |
1279 | presult = canv->GetPad(1); | |
1280 | pres = canv->GetPad(2); | |
1281 | ppen = canv->GetPad(3); | |
1282 | if (presult == 0 || pres == 0 || ppen == 0) { | |
1283 | canv->Clear(); | |
1284 | MakePads(); | |
1285 | blankCanvas = 1; | |
1286 | presult = canv->GetPad(1); | |
1287 | pres = canv->GetPad(2); | |
1288 | ppen = canv->GetPad(3); | |
1289 | } | |
1290 | } | |
1291 | else { | |
1292 | presult = new TCanvas; | |
1293 | pres = new TCanvas; | |
1294 | ppen = new TCanvas; | |
1295 | } | |
1296 | ||
1297 | ||
1298 | if (fgMaxInput == -1) | |
1299 | { | |
1300 | Printf("AliUnfolding::Unfold: WARNING. Number of measured bins not set with SetNbins. Using number of bins in measured distribution"); | |
1301 | fgMaxInput = measured->GetNbinsX(); | |
1302 | } | |
1303 | if (fgMaxParams == -1) | |
1304 | { | |
1305 | Printf("AliUnfolding::Unfold: WARNING. Number of unfolded bins not set with SetNbins. Using number of bins in measured distribution"); | |
1306 | fgMaxParams = initialConditions->GetNbinsX(); | |
1307 | } | |
1308 | ||
1309 | if (fgOverflowBinLimit > 0) | |
1310 | CreateOverflowBin(correlation, measured); | |
1311 | ||
1312 | // Uses Minuit methods | |
1313 | ||
1314 | SetStaticVariables(correlation, measured, efficiency); | |
1315 | ||
1316 | Double_t* params = new Double_t[fgMaxParams+1]; | |
1317 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1318 | { | |
1319 | params[i] = initialConditions->GetBinContent(i+1) * efficiency->GetBinContent(i+1); | |
1320 | ||
1321 | Bool_t fix = kFALSE; | |
1322 | if (params[i] < 0) | |
1323 | { | |
1324 | fix = kTRUE; | |
1325 | params[i] = -params[i]; | |
1326 | } | |
1327 | params[i]=TMath::Sqrt(params[i]); | |
1328 | ||
1329 | //cout << "params[" << i << "] " << params[i] << endl; | |
1330 | ||
1331 | } | |
1332 | ||
1333 | Double_t chi2; | |
1334 | Int_t dummy; | |
1335 | ||
1336 | //fgPrintChi2Details = kTRUE; | |
1337 | fgCallCount = 0; // To make sure that Chi2Function prints the components | |
1338 | Chi2Function(dummy, 0, chi2, params, 0); | |
1339 | ||
1340 | presult->cd(); | |
03650114 | 1341 | TH1 *meas2 = (TH1*)measured->Clone("meas2"); |
1342 | meas2->SetTitle("meas2"); | |
1343 | meas2->SetName("meas2"); | |
9e065ad2 | 1344 | meas2->SetLineColor(1); |
1345 | meas2->SetLineWidth(2); | |
1346 | meas2->SetMarkerColor(meas2->GetLineColor()); | |
1347 | meas2->SetMarkerStyle(20); | |
1348 | Float_t scale = unfolded->GetXaxis()->GetBinWidth(1)/meas2->GetXaxis()->GetBinWidth(1); | |
1349 | meas2->Scale(scale); | |
1350 | if (blankCanvas) | |
1351 | meas2->DrawCopy(); | |
1352 | else | |
1353 | meas2->DrawCopy("same"); | |
1354 | //meas2->GetXaxis()->SetLimits(0,fgMaxInput); | |
1355 | meas2->SetBit(kCannotPick); | |
1356 | DrawGuess(params, presult, pres, ppen, reuseHists,unfolded); | |
2d99332c | 1357 | delete [] params; |
9e065ad2 | 1358 | } |
1359 | //____________________________________________________________________ | |
1360 | void AliUnfolding::RedrawInteractive() { | |
1361 | // | |
1362 | // Helper function for interactive unfolding | |
1363 | // | |
1364 | DrawResults(fghCorrelation,fghEfficiency,fghMeasured,fghUnfolded,fgCanvas,1,fghUnfolded); | |
1365 | } | |
1366 | //____________________________________________________________________ | |
1367 | void AliUnfolding::InteractiveUnfold(TH2* correlation, TH1* efficiency, TH1* measured, TH1* initialConditions) | |
1368 | { | |
1369 | // | |
1370 | // Function to do interactive unfolding | |
1371 | // A canvas is drawn with the unfolding result | |
1372 | // Change the histogram with your mouse and all histograms | |
1373 | // will be updated automatically | |
1374 | ||
1375 | fgCanvas = new TCanvas("UnfoldingCanvas","Interactive unfolding",500,800); | |
1376 | fgCanvas->cd(); | |
1377 | ||
1378 | MakePads(); | |
1379 | ||
1380 | if (fghUnfolded) { | |
1381 | delete fghUnfolded; fghUnfolded = 0; | |
1382 | } | |
1383 | ||
1384 | gROOT->SetEditHistograms(kTRUE); | |
1385 | ||
03650114 | 1386 | fghUnfolded = new TH1F("AliUnfoldingfghUnfolded","Unfolded result (Interactive unfolder",efficiency->GetNbinsX(),efficiency->GetXaxis()->GetXmin(),efficiency->GetXaxis()->GetXmax()); |
9e065ad2 | 1387 | |
1388 | fghCorrelation = correlation; | |
1389 | fghEfficiency = efficiency; | |
1390 | fghMeasured = measured; | |
1391 | ||
03650114 | 1392 | if(fgMinuitMaxIterations>0) |
1393 | UnfoldWithMinuit(correlation,efficiency,measured,initialConditions,fghUnfolded,kFALSE); | |
1394 | else | |
1395 | fghUnfolded = initialConditions; | |
1396 | ||
1397 | fghUnfolded->SetLineColor(2); | |
1398 | fghUnfolded->SetMarkerColor(2); | |
1399 | fghUnfolded->SetLineWidth(2); | |
1400 | ||
9e065ad2 | 1401 | |
1402 | fgCanvas->cd(1); | |
1403 | fghUnfolded->Draw(); | |
1404 | DrawResults(correlation,efficiency,measured,fghUnfolded,fgCanvas,kFALSE,fghUnfolded); | |
1405 | ||
1406 | TExec *execRedraw = new TExec("redraw","AliUnfolding::RedrawInteractive()"); | |
1407 | fghUnfolded->GetListOfFunctions()->Add(execRedraw); | |
1408 | } | |
1409 | //____________________________________________________________________ | |
1410 | void AliUnfolding::DrawGuess(Double_t *params, TVirtualPad *pfolded, TVirtualPad *pres, TVirtualPad *ppen, Int_t reuseHists,TH1* unfolded) | |
19442b86 | 1411 | { |
1412 | // | |
1413 | // draws residuals of solution suggested by params and effect of regularization | |
1414 | // | |
1415 | ||
9e065ad2 | 1416 | if (pfolded == 0) |
1417 | pfolded = new TCanvas; | |
1418 | if (ppen == 0) | |
1419 | ppen = new TCanvas; | |
1420 | if (pres == 0) | |
1421 | pres = new TCanvas; | |
1422 | ||
19442b86 | 1423 | // d |
95e970ca | 1424 | TVectorD paramsVector(fgMaxParams); |
19442b86 | 1425 | for (Int_t i=0; i<fgMaxParams; ++i) |
1426 | paramsVector[i] = params[i] * params[i]; | |
1427 | ||
1428 | // Ad | |
1429 | TVectorD measGuessVector(fgMaxInput); | |
1430 | measGuessVector = (*fgCorrelationMatrix) * paramsVector; | |
1431 | ||
9e065ad2 | 1432 | TH1* folded = 0; |
1433 | if (reuseHists) | |
1434 | folded = dynamic_cast<TH1*>(gROOT->FindObject("__hfolded")); | |
1435 | if (!reuseHists || folded == 0) { | |
1436 | if (fgMeasuredAxis->GetXbins()->GetArray()) // variable bins | |
1437 | folded = new TH1F("__hfolded","Folded histo from AliUnfolding",fgMeasuredAxis->GetNbins(),fgMeasuredAxis->GetXbins()->GetArray()); | |
1438 | else | |
1439 | folded = new TH1F("__hfolded","Folded histo from AliUnfolding",fgMeasuredAxis->GetNbins(),fgMeasuredAxis->GetXmin(),fgMeasuredAxis->GetXmax()); | |
1440 | } | |
1441 | ||
1442 | folded->SetBit(kCannotPick); | |
1443 | folded->SetLineColor(4); | |
1444 | folded->SetLineWidth(2); | |
1445 | ||
1446 | for (Int_t ibin =0; ibin < fgMaxInput; ibin++) | |
1447 | folded->SetBinContent(ibin+1, measGuessVector[ibin]); | |
1448 | ||
1449 | Float_t scale = unfolded->GetXaxis()->GetBinWidth(1)/folded->GetXaxis()->GetBinWidth(1); | |
1450 | folded->Scale(scale); | |
1451 | ||
1452 | pfolded->cd(); | |
1453 | ||
1454 | folded->Draw("same"); | |
1455 | ||
19442b86 | 1456 | // Ad - m |
1457 | measGuessVector -= (*fgCurrentESDVector); | |
1458 | ||
1459 | TVectorD copy(measGuessVector); | |
19442b86 | 1460 | |
1461 | // (Ad - m) W | |
1462 | // this step can be optimized because currently only the diagonal elements of fgCorrelationCovarianceMatrix are used | |
1463 | // normal way is like this: | |
1464 | // measGuessVector *= (*fgCorrelationCovarianceMatrix); | |
1465 | // optimized way like this: | |
1466 | for (Int_t i=0; i<fgMaxInput; ++i) | |
1467 | measGuessVector[i] *= (*fgCorrelationCovarianceMatrix)(i, i); | |
1468 | ||
1469 | // (Ad - m) W (Ad - m) | |
1470 | // the factor 1e6 prevents that a very small number (measGuessVector[i]) is multiplied with a very | |
1471 | // big number ((*fgCorrelationCovarianceMatrix)(i, i)) (see ApplyMinuitFit) | |
1472 | //Double_t chi2FromFit = measGuessVector * copy * 1e6; | |
1473 | ||
1474 | // draw residuals | |
9e065ad2 | 1475 | // Double_t pTarray[fgMaxParams+1]; |
1476 | // for(int i=0; i<fgMaxParams; i++) { | |
1477 | // pTarray[i] = fgUnfoldedAxis->GetBinCenter(i)-0.5*fgUnfoldedAxis->GetBinWidth(i); | |
1478 | // } | |
1479 | // pTarray[fgMaxParams] = fgUnfoldedAxis->GetBinCenter(fgMaxParams-1)+0.5*fgUnfoldedAxis->GetBinWidth(fgMaxParams-1); | |
1480 | // TH1* residuals = new TH1F("residuals", "residuals", fgMaxParams,pTarray); | |
1481 | // TH1* residuals = new TH1F("residuals", "residuals", fgMaxInput, -0.5, fgMaxInput - 0.5); | |
1482 | // for (Int_t i=0; i<fgMaxInput; ++i) | |
1483 | // residuals->SetBinContent(i+1, measGuessVector(i) * copy(i) * 1e6);7 | |
1484 | TH1* residuals = GetResidualsPlot(params); | |
1485 | residuals->GetXaxis()->SetTitleSize(0.06); | |
1486 | residuals->GetXaxis()->SetTitleOffset(0.7); | |
1487 | residuals->GetXaxis()->SetLabelSize(0.07); | |
1488 | residuals->GetYaxis()->SetTitleSize(0.08); | |
1489 | residuals->GetYaxis()->SetTitleOffset(0.5); | |
1490 | residuals->GetYaxis()->SetLabelSize(0.06); | |
1491 | pres->cd(); residuals->DrawCopy(); gPad->SetLogy(); | |
1492 | ||
19442b86 | 1493 | |
1494 | // draw penalty | |
95e970ca | 1495 | TH1* penalty = GetPenaltyPlot(params); |
9e065ad2 | 1496 | penalty->GetXaxis()->SetTitleSize(0.06); |
1497 | penalty->GetXaxis()->SetTitleOffset(0.7); | |
1498 | penalty->GetXaxis()->SetLabelSize(0.07); | |
1499 | penalty->GetYaxis()->SetTitleSize(0.08); | |
1500 | penalty->GetYaxis()->SetTitleOffset(0.5); | |
1501 | penalty->GetYaxis()->SetLabelSize(0.06); | |
1502 | ppen->cd(); penalty->DrawCopy(); gPad->SetLogy(); | |
1503 | } | |
1504 | ||
1505 | //____________________________________________________________________ | |
1506 | TH1* AliUnfolding::GetResidualsPlot(TH1* corrected) | |
1507 | { | |
1508 | // | |
1509 | // MvL: THIS MUST BE INCORRECT. | |
1510 | // Need heff to calculate params from TH1 'corrected' | |
1511 | // | |
1512 | ||
1513 | // | |
1514 | // fill residuals histogram of solution suggested by params and effect of regularization | |
1515 | // | |
1516 | ||
1517 | Double_t* params = new Double_t[fgMaxParams]; | |
b9b1eb8a | 1518 | for (Int_t i=0; i<fgMaxParams; i++) |
1519 | params[i] = 0; | |
1520 | ||
9e065ad2 | 1521 | for (Int_t i=0; i<TMath::Min(fgMaxParams, corrected->GetNbinsX()); i++) |
3a44f1b9 | 1522 | params[i] = TMath::Sqrt(TMath::Abs(corrected->GetBinContent(i+1)*(*fgEfficiency)(i))); |
9e065ad2 | 1523 | |
2d99332c | 1524 | TH1 * plot = GetResidualsPlot(params); |
1525 | delete [] params; | |
1526 | return plot; | |
9e065ad2 | 1527 | } |
1528 | ||
1529 | //____________________________________________________________________ | |
1530 | TH1* AliUnfolding::GetResidualsPlot(Double_t* params) | |
1531 | { | |
1532 | // | |
1533 | // fill residuals histogram of solution suggested by params and effect of regularization | |
1534 | // | |
1535 | ||
1536 | // d | |
1537 | TVectorD paramsVector(fgMaxParams); | |
1538 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1539 | paramsVector[i] = params[i] * params[i]; | |
1540 | ||
1541 | // Ad | |
1542 | TVectorD measGuessVector(fgMaxInput); | |
1543 | measGuessVector = (*fgCorrelationMatrix) * paramsVector; | |
1544 | ||
1545 | // Ad - m | |
1546 | measGuessVector -= (*fgCurrentESDVector); | |
1547 | ||
1548 | TVectorD copy(measGuessVector); | |
1549 | ||
1550 | // (Ad - m) W | |
1551 | // this step can be optimized because currently only the diagonal elements of fgCorrelationCovarianceMatrix are used | |
1552 | // normal way is like this: | |
1553 | // measGuessVector *= (*fgCorrelationCovarianceMatrix); | |
1554 | // optimized way like this: | |
1555 | for (Int_t i=0; i<fgMaxInput; ++i) | |
1556 | measGuessVector[i] *= (*fgCorrelationCovarianceMatrix)(i, i); | |
1557 | ||
1558 | // (Ad - m) W (Ad - m) | |
1559 | // the factor 1e6 prevents that a very small number (measGuessVector[i]) is multiplied with a very | |
1560 | // big number ((*fgCorrelationCovarianceMatrix)(i, i)) (see ApplyMinuitFit) | |
1561 | //Double_t chi2FromFit = measGuessVector * copy * 1e6; | |
1562 | ||
1563 | // draw residuals | |
1564 | TH1* residuals = 0; | |
1565 | if (fgMeasuredAxis->GetXbins()->GetArray()) // variable bins | |
1566 | residuals = new TH1F("residuals", "residuals;unfolded pos;residual",fgMeasuredAxis->GetNbins(),fgMeasuredAxis->GetXbins()->GetArray()); | |
1567 | else | |
1568 | residuals = new TH1F("residuals", "residuals;unfolded pos;residual",fgMeasuredAxis->GetNbins(),fgMeasuredAxis->GetXmin(), fgMeasuredAxis->GetXmax()); | |
1569 | // TH1* residuals = new TH1F("residuals", "residuals", fgMaxInput, -0.5, fgMaxInput - 0.5); | |
1570 | ||
1571 | Double_t sumResiduals = 0.; | |
1572 | for (Int_t i=0; i<fgMaxInput; ++i) { | |
1573 | residuals->SetBinContent(i+1, measGuessVector(i) * copy(i) * 1e6); | |
1574 | sumResiduals += measGuessVector(i) * copy(i) * 1e6; | |
1575 | } | |
1576 | fAvgResidual = sumResiduals/(double)fgMaxInput; | |
1577 | ||
1578 | return residuals; | |
95e970ca | 1579 | } |
19442b86 | 1580 | |
95e970ca | 1581 | //____________________________________________________________________ |
1582 | TH1* AliUnfolding::GetPenaltyPlot(TH1* corrected) | |
1583 | { | |
1584 | // draws the penalty factors as function of multiplicity of the current selected regularization | |
19442b86 | 1585 | |
95e970ca | 1586 | Double_t* params = new Double_t[fgMaxParams]; |
b9b1eb8a | 1587 | for (Int_t i=0; i<fgMaxParams; i++) |
1588 | params[i] = 0; | |
1589 | ||
95e970ca | 1590 | for (Int_t i=0; i<TMath::Min(fgMaxParams, corrected->GetNbinsX()); i++) |
9e065ad2 | 1591 | params[i] = (*fgEfficiency)(i)*corrected->GetBinContent(i+1); |
95e970ca | 1592 | |
1593 | TH1* penalty = GetPenaltyPlot(params); | |
1594 | ||
1595 | delete[] params; | |
1596 | ||
1597 | return penalty; | |
1598 | } | |
1599 | ||
1600 | //____________________________________________________________________ | |
1601 | TH1* AliUnfolding::GetPenaltyPlot(Double_t* params) | |
1602 | { | |
1603 | // draws the penalty factors as function of multiplicity of the current selected regularization | |
1604 | ||
9e065ad2 | 1605 | //TH1* penalty = new TH1F("penalty", ";unfolded multiplicity;penalty factor", fgMaxParams, -0.5, fgMaxParams - 0.5); |
1606 | // TH1* penalty = new TH1F("penalty", ";unfolded pos;penalty factor", fgMaxParams, fgUnfoldedAxis->GetBinCenter(0)-0.5*fgUnfoldedAxis->GetBinWidth(0),fgUnfoldedAxis->GetBinCenter(fgMaxParams)+0.5*fgUnfoldedAxis->GetBinWidth(fgMaxParams) ); | |
1607 | ||
1608 | TH1* penalty = 0; | |
1609 | if (fgUnfoldedAxis->GetXbins()->GetArray()) | |
1610 | penalty = new TH1F("penalty", ";unfolded pos;penalty factor", fgUnfoldedAxis->GetNbins(),fgUnfoldedAxis->GetXbins()->GetArray()); | |
1611 | else | |
1612 | penalty = new TH1F("penalty", ";unfolded pos;penalty factor", fgUnfoldedAxis->GetNbins(),fgUnfoldedAxis->GetXmin(),fgUnfoldedAxis->GetXmax()); | |
95e970ca | 1613 | |
1614 | for (Int_t i=1+fgSkipBinsBegin; i<fgMaxParams; ++i) | |
19442b86 | 1615 | { |
95e970ca | 1616 | Double_t diff = 0; |
1617 | if (fgRegularizationType == kPol0) | |
1618 | { | |
9e065ad2 | 1619 | Double_t right = params[i] / fgUnfoldedAxis->GetBinWidth(i+1); |
1620 | Double_t left = params[i-1] / fgUnfoldedAxis->GetBinWidth(i); | |
19442b86 | 1621 | |
95e970ca | 1622 | if (left != 0) |
1623 | { | |
1624 | Double_t diffTmp = (right - left); | |
9e065ad2 | 1625 | diff = diffTmp * diffTmp / left / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2) / 100; |
95e970ca | 1626 | } |
1627 | } | |
1628 | if (fgRegularizationType == kPol1 && i > 1+fgSkipBinsBegin) | |
1629 | { | |
1630 | if (params[i-1] == 0) | |
1631 | continue; | |
19442b86 | 1632 | |
9e065ad2 | 1633 | Double_t right = params[i] / fgUnfoldedAxis->GetBinWidth(i+1); |
1634 | Double_t middle = params[i-1] / fgUnfoldedAxis->GetBinWidth(i); | |
1635 | Double_t left = params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1); | |
19442b86 | 1636 | |
9e065ad2 | 1637 | Double_t der1 = (right - middle) / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); |
1638 | Double_t der2 = (middle - left) / ((fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i-1)) / 2); | |
95e970ca | 1639 | |
1640 | diff = (der1 - der2) * (der1 - der2) / middle; | |
1641 | } | |
9e065ad2 | 1642 | |
95e970ca | 1643 | if (fgRegularizationType == kLog && i > 1+fgSkipBinsBegin) |
1644 | { | |
1645 | if (params[i-1] == 0) | |
1646 | continue; | |
1647 | ||
1648 | Double_t right = log(params[i]); | |
1649 | Double_t middle = log(params[i-1]); | |
1650 | Double_t left = log(params[i-2]); | |
1651 | ||
1652 | Double_t der1 = (right - middle); | |
1653 | Double_t der2 = (middle - left); | |
1654 | ||
1655 | //Double_t error = 1. / params[i] + 4. / params[i-1] + 1. / params[i-2]; | |
1656 | //Printf("%d %f %f", i, (der1 - der2) * (der1 - der2), error); | |
1657 | ||
1658 | diff = (der1 - der2) * (der1 - der2);// / error; | |
1659 | } | |
9e065ad2 | 1660 | if (fgRegularizationType == kCurvature && i > 1+fgSkipBinsBegin) |
1661 | { | |
1662 | Double_t right = params[i]; // params are sqrt | |
1663 | Double_t middle = params[i-1]; | |
1664 | Double_t left = params[i-2]; | |
1665 | ||
1666 | Double_t der1 = (right - middle)/0.5/(fgUnfoldedAxis->GetBinWidth(i-1) + fgUnfoldedAxis->GetBinWidth(i)); | |
1667 | Double_t der2 = (middle - left)/0.5/(fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i+1)); | |
1668 | ||
1669 | diff = (der1 - der2)/(fgUnfoldedAxis->GetBinWidth(i-1) + fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i-1))*3.0; | |
1670 | diff = 1e4*diff*diff; | |
1671 | } | |
1672 | if (fgRegularizationType == kPowerLaw && i > 1+fgSkipBinsBegin) | |
1673 | { | |
19442b86 | 1674 | |
9e065ad2 | 1675 | if (params[i] < 1e-8 || params[i-1] < 1e-8 || params[i-2] < 1e-8) |
1676 | continue; | |
1677 | ||
1678 | if (fgUnfoldedAxis->GetBinWidth(i+1) < 1e-8 || fgUnfoldedAxis->GetBinWidth(i) < 1e-8 || fgUnfoldedAxis->GetBinWidth(i) < 1e-8) | |
1679 | continue; | |
1680 | ||
1681 | double middle = TMath::Power(params[i-1] / fgUnfoldedAxis->GetBinWidth(i),fgPowern); | |
1682 | ||
1683 | if(middle>0) { | |
1684 | double right = TMath::Power(params[i] / fgUnfoldedAxis->GetBinWidth(i+1),fgPowern)/middle; | |
1685 | ||
1686 | double left = TMath::Power(params[i-2] / fgUnfoldedAxis->GetBinWidth(i-1),fgPowern)/middle; | |
1687 | ||
1688 | middle = 1.; | |
1689 | ||
1690 | Double_t der1 = (right - middle) / ((fgUnfoldedAxis->GetBinWidth(i+1) + fgUnfoldedAxis->GetBinWidth(i)) / 2); | |
1691 | Double_t der2 = (middle - left) / ((fgUnfoldedAxis->GetBinWidth(i) + fgUnfoldedAxis->GetBinWidth(i-1)) / 2); | |
1692 | ||
1693 | diff = (der1 - der2) * (der1 - der2);// / error; | |
1694 | } | |
1695 | } | |
1696 | ||
1697 | if (fgRegularizationType == kLogLog && i > 1+fgSkipBinsBegin) | |
1698 | { | |
1699 | ||
1700 | if (params[i] < 1e-8 || params[i-1] < 1e-8 || params[i-2] < 1e-8) | |
1701 | continue; | |
1702 | ||
1703 | Double_t right = log(params[i] / (*fgEfficiency)(i) / fgUnfoldedAxis->GetBinWidth(i+1)); | |
1704 | Double_t middle = log(params[i-1] / (*fgEfficiency)(i-1) / fgUnfoldedAxis->GetBinWidth(i)); | |
1705 | Double_t left = log(params[i-2] / (*fgEfficiency)(i-2) / fgUnfoldedAxis->GetBinWidth(i-1)); | |
1706 | ||
1707 | Double_t der1 = (right - middle) / ( log(fgUnfoldedAxis->GetBinCenter(i+1)) - log(fgUnfoldedAxis->GetBinCenter(i)) ); | |
1708 | Double_t der2 = (middle - left) /( log(fgUnfoldedAxis->GetBinCenter(i)) - log(fgUnfoldedAxis->GetBinCenter(i-1)) ); | |
1709 | ||
1710 | double tmp = (log(fgUnfoldedAxis->GetBinCenter(i+1)) - log(fgUnfoldedAxis->GetBinCenter(i-1)))/2.; | |
1711 | Double_t dder = (der1-der2) / tmp; | |
1712 | ||
1713 | diff = dder * dder; | |
1714 | } | |
1715 | ||
1716 | penalty->SetBinContent(i, diff*fgRegularizationWeight); | |
19442b86 | 1717 | |
1718 | //Printf("%d %f %f %f %f", i-1, left, middle, right, diff); | |
1719 | } | |
95e970ca | 1720 | |
1721 | return penalty; | |
19442b86 | 1722 | } |
1723 | ||
1724 | //____________________________________________________________________ | |
1725 | void AliUnfolding::TF1Function(Int_t& unused1, Double_t* unused2, Double_t& chi2, Double_t *params, Int_t unused3) | |
1726 | { | |
1727 | // | |
1728 | // fit function for minuit | |
1729 | // uses the TF1 stored in fgFitFunction | |
1730 | // | |
1731 | ||
1732 | for (Int_t i=0; i<fgFitFunction->GetNpar(); i++) | |
1733 | fgFitFunction->SetParameter(i, params[i]); | |
1734 | ||
1735 | Double_t* params2 = new Double_t[fgMaxParams]; | |
1736 | ||
1737 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1738 | params2[i] = fgFitFunction->Eval(i); | |
1739 | ||
1740 | Chi2Function(unused1, unused2, chi2, params2, unused3); | |
1741 | ||
1742 | delete[] params2; | |
1743 | ||
1744 | if (fgDebug) | |
1745 | Printf("%f", chi2); | |
1746 | } | |
1747 | ||
1748 | //____________________________________________________________________ | |
1749 | Int_t AliUnfolding::UnfoldWithFunction(TH2* correlation, TH1* efficiency, TH1* measured, TH1* /* initialConditions */, TH1* aResult) | |
1750 | { | |
1751 | // | |
1752 | // correct spectrum using minuit chi2 method applying a functional fit | |
1753 | // | |
1754 | ||
1755 | if (!fgFitFunction) | |
1756 | { | |
1757 | Printf("AliUnfolding::UnfoldWithFunction: ERROR fit function not set. Exiting."); | |
1758 | return -1; | |
1759 | } | |
1760 | ||
1761 | SetChi2Regularization(kNone, 0); | |
1762 | ||
95e970ca | 1763 | SetStaticVariables(correlation, measured, efficiency); |
19442b86 | 1764 | |
1765 | // Initialize TMinuit via generic fitter interface | |
1766 | TVirtualFitter *minuit = TVirtualFitter::Fitter(0, fgFitFunction->GetNpar()); | |
1767 | ||
1768 | minuit->SetFCN(TF1Function); | |
1769 | for (Int_t i=0; i<fgFitFunction->GetNpar(); i++) | |
1770 | { | |
1771 | Double_t lower, upper; | |
1772 | fgFitFunction->GetParLimits(i, lower, upper); | |
1773 | minuit->SetParameter(i, Form("param%d",i), fgFitFunction->GetParameter(i), fgMinuitStepSize, lower, upper); | |
1774 | } | |
1775 | ||
1776 | Double_t arglist[100]; | |
1777 | arglist[0] = 0; | |
1778 | minuit->ExecuteCommand("SET PRINT", arglist, 1); | |
9e065ad2 | 1779 | minuit->ExecuteCommand("SCAN", arglist, 0); |
19442b86 | 1780 | minuit->ExecuteCommand("MIGRAD", arglist, 0); |
1781 | //minuit->ExecuteCommand("MINOS", arglist, 0); | |
1782 | ||
1783 | for (Int_t i=0; i<fgFitFunction->GetNpar(); i++) | |
1784 | fgFitFunction->SetParameter(i, minuit->GetParameter(i)); | |
1785 | ||
1786 | for (Int_t i=0; i<fgMaxParams; ++i) | |
1787 | { | |
1788 | Double_t value = fgFitFunction->Eval(i); | |
1789 | if (fgDebug) | |
1790 | Printf("%d : %f", i, value); | |
1791 | ||
1792 | if (efficiency) | |
1793 | { | |
1794 | if (efficiency->GetBinContent(i+1) > 0) | |
1795 | { | |
1796 | value /= efficiency->GetBinContent(i+1); | |
1797 | } | |
1798 | else | |
1799 | value = 0; | |
1800 | } | |
1801 | aResult->SetBinContent(i+1, value); | |
1802 | aResult->SetBinError(i+1, 0); | |
1803 | } | |
1804 | ||
1805 | return 0; | |
1806 | } | |
1807 | ||
1808 | //____________________________________________________________________ | |
1809 | void AliUnfolding::CreateOverflowBin(TH2* correlation, TH1* measured) | |
1810 | { | |
1811 | // Finds the first bin where the content is below fgStatLimit and combines all values for this bin and larger bins | |
1812 | // The same limit is applied to the correlation | |
1813 | ||
1814 | Int_t lastBin = 0; | |
1815 | for (Int_t i=1; i<=measured->GetNbinsX(); ++i) | |
1816 | { | |
1817 | if (measured->GetBinContent(i) <= fgOverflowBinLimit) | |
1818 | { | |
1819 | lastBin = i; | |
1820 | break; | |
1821 | } | |
1822 | } | |
1823 | ||
1824 | if (lastBin == 0) | |
1825 | { | |
1826 | Printf("AliUnfolding::CreateOverflowBin: WARNING: First bin is already below limit of %f", fgOverflowBinLimit); | |
1827 | return; | |
1828 | } | |
1829 | ||
1830 | Printf("AliUnfolding::CreateOverflowBin: Bin limit in measured spectrum determined to be %d", lastBin); | |
1831 | ||
1832 | TCanvas* canvas = 0; | |
1833 | ||
1834 | if (fgDebug) | |
1835 | { | |
1836 | canvas = new TCanvas("StatSolution", "StatSolution", 1000, 800); | |
1837 | canvas->Divide(2, 2); | |
1838 | ||
1839 | canvas->cd(1); | |
1840 | measured->SetStats(kFALSE); | |
1841 | measured->DrawCopy(); | |
1842 | gPad->SetLogy(); | |
1843 | ||
1844 | canvas->cd(2); | |
1845 | correlation->SetStats(kFALSE); | |
1846 | correlation->DrawCopy("COLZ"); | |
1847 | } | |
1848 | ||
1849 | measured->SetBinContent(lastBin, measured->Integral(lastBin, measured->GetNbinsX())); | |
1850 | for (Int_t i=lastBin+1; i<=measured->GetNbinsX(); ++i) | |
1851 | { | |
1852 | measured->SetBinContent(i, 0); | |
1853 | measured->SetBinError(i, 0); | |
1854 | } | |
1855 | // the error is set to sqrt(N), better solution possible?, sum of relative errors of all contributions??? | |
1856 | measured->SetBinError(lastBin, TMath::Sqrt(measured->GetBinContent(lastBin))); | |
1857 | ||
1858 | Printf("AliUnfolding::CreateOverflowBin: This bin has now %f +- %f entries", measured->GetBinContent(lastBin), measured->GetBinError(lastBin)); | |
1859 | ||
1860 | for (Int_t i=1; i<=correlation->GetNbinsX(); ++i) | |
1861 | { | |
1862 | correlation->SetBinContent(i, lastBin, correlation->Integral(i, i, lastBin, correlation->GetNbinsY())); | |
1863 | // the error is set to sqrt(N), better solution possible?, sum of relative errors of all contributions??? | |
1864 | correlation->SetBinError(i, lastBin, TMath::Sqrt(correlation->GetBinContent(i, lastBin))); | |
1865 | ||
1866 | for (Int_t j=lastBin+1; j<=correlation->GetNbinsY(); ++j) | |
1867 | { | |
1868 | correlation->SetBinContent(i, j, 0); | |
1869 | correlation->SetBinError(i, j, 0); | |
1870 | } | |
1871 | } | |
1872 | ||
1873 | Printf("AliUnfolding::CreateOverflowBin: Adjusted correlation matrix!"); | |
1874 | ||
1875 | if (canvas) | |
1876 | { | |
1877 | canvas->cd(3); | |
1878 | measured->DrawCopy(); | |
1879 | gPad->SetLogy(); | |
1880 | ||
1881 | canvas->cd(4); | |
1882 | correlation->DrawCopy("COLZ"); | |
1883 | } | |
1884 | } | |
95e970ca | 1885 | |
1886 | Int_t AliUnfolding::UnfoldGetBias(TH2* correlation, TH1* efficiency, TH1* measured, TH1* initialConditions, TH1* result) | |
1887 | { | |
1888 | // unfolds and assigns bias as errors with Eq. 19 of Cowan, "a survey of unfolding methods for particle physics" | |
1889 | // b_i = sum_j dmu_i/dn_j (nu_j - n_j) with nu_j as folded guess, n_j as data | |
1890 | // dmu_i/dn_j is found numerically by changing the bin content and re-unfolding | |
1891 | // | |
1892 | // return code: 0 (success) -1 (error: from Unfold(...) ) | |
1893 | ||
1894 | if (Unfold(correlation, efficiency, measured, initialConditions, result) != 0) | |
1895 | return -1; | |
1896 | ||
1897 | TMatrixD matrix(fgMaxInput, fgMaxParams); | |
1898 | ||
1899 | TH1* newResult[4]; | |
1900 | for (Int_t loop=0; loop<4; loop++) | |
1901 | newResult[loop] = (TH1*) result->Clone(Form("newresult_%d", loop)); | |
1902 | ||
1903 | // change bin-by-bin and built matrix of effects | |
1904 | for (Int_t m=0; m<fgMaxInput; m++) | |
1905 | { | |
1906 | if (measured->GetBinContent(m+1) < 1) | |
1907 | continue; | |
1908 | ||
1909 | for (Int_t loop=0; loop<4; loop++) | |
1910 | { | |
1911 | //Printf("%d %d", i, loop); | |
1912 | Float_t factor = 1; | |
1913 | switch (loop) | |
1914 | { | |
1915 | case 0: factor = 0.5; break; | |
1916 | case 1: factor = -0.5; break; | |
1917 | case 2: factor = 1; break; | |
1918 | case 3: factor = -1; break; | |
1919 | default: return -1; | |
1920 | } | |
1921 | ||
1922 | TH1* measuredClone = (TH1*) measured->Clone("measuredClone"); | |
1923 | ||
1924 | measuredClone->SetBinContent(m+1, measured->GetBinContent(m+1) + factor * TMath::Sqrt(measured->GetBinContent(m+1))); | |
1925 | //new TCanvas; measuredClone->Draw("COLZ"); | |
1926 | ||
1927 | newResult[loop]->Reset(); | |
1928 | Unfold(correlation, efficiency, measuredClone, measuredClone, newResult[loop]); | |
1929 | // WARNING if we leave here, then nothing is calculated | |
1930 | //return -1; | |
1931 | ||
1932 | delete measuredClone; | |
1933 | } | |
1934 | ||
1935 | for (Int_t t=0; t<fgMaxParams; t++) | |
1936 | { | |
1937 | // one value | |
1938 | //matrix(i, j) = (result->GetBinContent(j+1) - newResult->GetBinContent(j+1)) / TMath::Sqrt(changedHist->GetBinContent(1, i+1)); | |
1939 | ||
1940 | // four values from the derivate (procedure taken from ROOT -- suggestion by Ruben) | |
1941 | // = 1/2D * [ 8 (f(D/2) - f(-D/2)) - (f(D)-f(-D)) ]/3 | |
1942 | ||
1943 | /* | |
1944 | // check formula | |
1945 | measured->SetBinContent(1, m+1, 100); | |
1946 | newResult[0]->SetBinContent(t+1, 5 * 0.5 + 10); | |
1947 | newResult[1]->SetBinContent(t+1, 5 * -0.5 + 10); | |
1948 | newResult[2]->SetBinContent(t+1, 5 * 1 + 10); | |
1949 | newResult[3]->SetBinContent(t+1, 5 * -1 + 10); | |
1950 | */ | |
1951 | ||
1952 | matrix(m, t) = 0.5 / TMath::Sqrt(measured->GetBinContent(m+1)) * | |
1953 | ( 8. * (newResult[0]->GetBinContent(t+1) - newResult[1]->GetBinContent(t+1)) - | |
1954 | (newResult[2]->GetBinContent(t+1) - newResult[3]->GetBinContent(t+1)) | |
1955 | ) / 3; | |
1956 | } | |
1957 | } | |
1958 | ||
1959 | for (Int_t loop=0; loop<4; loop++) | |
1960 | delete newResult[loop]; | |
1961 | ||
95e970ca | 1962 | // ...calculate folded guess |
1963 | TH1* convoluted = (TH1*) measured->Clone("convoluted"); | |
1964 | convoluted->Reset(); | |
1965 | for (Int_t m=0; m<fgMaxInput; m++) | |
1966 | { | |
1967 | Float_t value = 0; | |
1968 | for (Int_t t = 0; t<fgMaxParams; t++) | |
1969 | { | |
1970 | Float_t tmp = correlation->GetBinContent(t+1, m+1) * result->GetBinContent(t+1); | |
1971 | if (efficiency) | |
1972 | tmp *= efficiency->GetBinContent(t+1); | |
1973 | value += tmp; | |
1974 | } | |
1975 | convoluted->SetBinContent(m+1, value); | |
1976 | } | |
1977 | ||
1978 | // rescale | |
1979 | convoluted->Scale(measured->Integral() / convoluted->Integral()); | |
1980 | ||
1981 | //new TCanvas; convoluted->Draw(); measured->Draw("SAME"); measured->SetLineColor(2); | |
1982 | //return; | |
1983 | ||
1984 | // difference | |
1985 | convoluted->Add(measured, -1); | |
1986 | ||
1987 | // ...and the bias | |
1988 | for (Int_t t = 0; t<fgMaxParams; t++) | |
1989 | { | |
1990 | Double_t error = 0; | |
1991 | for (Int_t m=0; m<fgMaxInput; m++) | |
1992 | error += matrix(m, t) * convoluted->GetBinContent(m+1); | |
1993 | result->SetBinError(t+1, error); | |
1994 | } | |
1995 | ||
1996 | //new TCanvas; result->Draw(); gPad->SetLogy(); | |
1997 | ||
1998 | return 0; | |
1999 | } |