source: trunk/MagicSoft/Mars/mcalib/MHGausEvents.cc@ 3551

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1/* ======================================================================== *\
2!
3! *
4! * This file is part of MARS, the MAGIC Analysis and Reconstruction
5! * Software. It is distributed to you in the hope that it can be a useful
6! * and timesaving tool in analysing Data of imaging Cerenkov telescopes.
7! * It is distributed WITHOUT ANY WARRANTY.
8! *
9! * Permission to use, copy, modify and distribute this software and its
10! * documentation for any purpose is hereby granted without fee,
11! * provided that the above copyright notice appear in all copies and
12! * that both that copyright notice and this permission notice appear
13! * in supporting documentation. It is provided "as is" without express
14! * or implied warranty.
15! *
16!
17!
18! Author(s): Markus Gaug 02/2004 <mailto:markus@ifae.es>
19!
20! Copyright: MAGIC Software Development, 2000-2004
21!
22!
23\* ======================================================================== */
24
25//////////////////////////////////////////////////////////////////////////////
26//
27// MHGausEvents
28//
29// A base class for events which are believed follow a Gaussian distribution
30// with time, (e.g. calibration events, observables containing white noise, etc.)
31//
32// MHGausEvents derives from MH, thus all features of MH can be used by a class
33// deriving from MHGausEvents, especially the filling functions.
34//
35// The central objects are:
36//
37// 1) The TH1F fHGausHist:
38// ==============================
39//
40// It is created with a default name and title and resides in directory NULL.
41// - Any class deriving from MHGausEvents needs to apply a binning to fHGausHist
42// (e.g. with the function TH1F::SetBins(..) )
43// - The histogram is filled with the functions FillHist or FillHistAndArray.
44// - The histogram can be fitted with the function FitGaus(). This involves stripping
45// of all zeros at the lower and upper end of the histogram and re-binning to
46// a new number of bins, specified in the variable fBinsAfterStripping.
47// - The fit result's probability is compared to a reference probability fProbLimit
48// The NDF is compared to fNDFLimit and a check is made whether results are NaNs.
49// Accordingly the flag GausFitOK is set.
50//
51// 2) The TArrayF fEvents:
52// ==========================
53//
54// It is created with 0 entries and not expanded unless FillArray or FillHistAndArray is called.
55// - A first call to FillArray or FillHistAndArray initializes fEvents by default to 512 entries.
56// - Any later call to FillArray or FillHistAndArray fills up the array. Reaching the limit,
57// the array is expanded by a factor 2.
58// - The array can be fourier-transformed into the array fPowerSpectrum. Note that any FFT accepts
59// only number of events which are a power of 2. Thus, fEvents is cut to the next power of 2 smaller
60// than its actual number of entries. You might lose information at the end of your analysis.
61// - Calling the function CreateFourierTransform creates the array fPowerSpectrum and its projection
62// fHPowerProbability which in turn is fit to an exponential.
63// - The fit result's probability is compared to a referenc probability fProbLimit
64// and accordingly the flag ExpFitOK is set.
65// - The flag FourierSpectrumOK is set accordingly to ExpFitOK. Later, a closer check will be
66// installed.
67// - You can display all arrays by calls to: CreateGraphEvents() and CreateGraphPowerSpectrum() and
68// successive calls to the corresponding Getters.
69//
70//////////////////////////////////////////////////////////////////////////////
71#include "MHGausEvents.h"
72
73#include <TH1.h>
74#include <TF1.h>
75#include <TGraph.h>
76#include <TPad.h>
77#include <TVirtualPad.h>
78#include <TCanvas.h>
79#include <TStyle.h>
80
81#include "MFFT.h"
82#include "MArray.h"
83
84#include "MH.h"
85
86#include "MLog.h"
87#include "MLogManip.h"
88
89ClassImp(MHGausEvents);
90
91using namespace std;
92
93const Float_t MHGausEvents::fgProbLimit = 0.001;
94const Int_t MHGausEvents::fgNDFLimit = 2;
95const Int_t MHGausEvents::fgPowerProbabilityBins = 20;
96const Int_t MHGausEvents::fgBinsAfterStripping = 40;
97// --------------------------------------------------------------------------
98//
99// Default Constructor.
100//
101MHGausEvents::MHGausEvents(const char *name, const char *title)
102 : fHPowerProbability(NULL),
103 fPowerSpectrum(NULL),
104 fGraphEvents(NULL), fGraphPowerSpectrum(NULL),
105 fHGausHist(), fEvents(0),
106 fFGausFit(NULL), fFExpFit(NULL)
107{
108
109 fName = name ? name : "MHGausEvents";
110 fTitle = title ? title : "Events with expected Gaussian distributions";
111
112 Clear();
113
114 SetPowerProbabilityBins();
115 SetEventFrequency();
116 SetProbLimit();
117 SetNDFLimit();
118 SetBinsAfterStripping();
119
120 fHGausHist.SetName("HGausHist");
121 fHGausHist.SetTitle("Histogram of Events with Gaussian Distribution");
122 // important, other ROOT will not draw the axes:
123 fHGausHist.UseCurrentStyle();
124 fHGausHist.SetDirectory(NULL);
125}
126
127
128
129
130MHGausEvents::~MHGausEvents()
131{
132
133 // delete histograms
134 if (fHPowerProbability)
135 delete fHPowerProbability;
136
137 // delete fits
138 if (fFGausFit)
139 delete fFGausFit;
140 if (fFExpFit)
141 delete fFExpFit;
142
143 // delete arrays
144 if (fPowerSpectrum)
145 delete fPowerSpectrum;
146
147 // delete graphs
148 if (fGraphEvents)
149 delete fGraphEvents;
150 if (fGraphPowerSpectrum)
151 delete fGraphPowerSpectrum;
152}
153
154
155void MHGausEvents::Clear(Option_t *o)
156{
157
158 SetGausFitOK ( kFALSE );
159 SetExpFitOK ( kFALSE );
160 SetFourierSpectrumOK( kFALSE );
161
162 fMean = 0.;
163 fSigma = 0.;
164 fMeanErr = 0.;
165 fSigmaErr = 0.;
166 fProb = 0.;
167
168 fCurrentSize = 0;
169
170 if (fHPowerProbability)
171 delete fHPowerProbability;
172
173 // delete fits
174 if (fFGausFit)
175 delete fFGausFit;
176 if (fFExpFit)
177 delete fFExpFit;
178
179 // delete arrays
180 if (fPowerSpectrum)
181 delete fPowerSpectrum;
182
183 // delete graphs
184 if (fGraphEvents)
185 delete fGraphEvents;
186 if (fGraphPowerSpectrum)
187 delete fGraphPowerSpectrum;
188}
189
190
191void MHGausEvents::Reset()
192{
193
194 Clear();
195 fHGausHist.Reset();
196 fEvents.Set(0);
197
198}
199
200
201Bool_t MHGausEvents::FillHistAndArray(const Float_t f)
202{
203
204 FillArray(f);
205 return FillHist(f);
206}
207
208Bool_t MHGausEvents::FillHist(const Float_t f)
209{
210
211 if (fHGausHist.Fill(f) == -1)
212 return kFALSE;
213
214 return kTRUE;
215}
216
217void MHGausEvents::FillArray(const Float_t f)
218{
219 if (fEvents.GetSize() == 0)
220 fEvents.Set(512);
221
222 if (fCurrentSize >= fEvents.GetSize())
223 fEvents.Set(fEvents.GetSize()*2);
224
225 fEvents.AddAt(f,fCurrentSize++);
226}
227
228
229const Double_t MHGausEvents::GetChiSquare() const
230{
231 return ( fFGausFit ? fFGausFit->GetChisquare() : 0.);
232}
233
234const Int_t MHGausEvents::GetNdf() const
235{
236 return ( fFGausFit ? fFGausFit->GetNDF() : 0);
237}
238
239
240const Double_t MHGausEvents::GetExpChiSquare() const
241{
242 return ( fFExpFit ? fFExpFit->GetChisquare() : 0.);
243}
244
245
246const Int_t MHGausEvents::GetExpNdf() const
247{
248 return ( fFExpFit ? fFExpFit->GetNDF() : 0);
249}
250
251
252const Double_t MHGausEvents::GetExpProb() const
253{
254 return ( fFExpFit ? fFExpFit->GetProb() : 0.);
255}
256
257
258const Double_t MHGausEvents::GetOffset() const
259{
260 return ( fFExpFit ? fFExpFit->GetParameter(0) : 0.);
261}
262
263
264const Double_t MHGausEvents::GetSlope() const
265{
266 return ( fFExpFit ? fFExpFit->GetParameter(1) : 0.);
267}
268
269
270const Bool_t MHGausEvents::IsEmpty() const
271{
272 return !(fHGausHist.GetEntries());
273}
274
275
276const Bool_t MHGausEvents::IsFourierSpectrumOK() const
277{
278 return TESTBIT(fFlags,kFourierSpectrumOK);
279}
280
281
282const Bool_t MHGausEvents::IsGausFitOK() const
283{
284 return TESTBIT(fFlags,kGausFitOK);
285}
286
287
288const Bool_t MHGausEvents::IsExpFitOK() const
289{
290 return TESTBIT(fFlags,kExpFitOK);
291}
292
293
294// -------------------------------------------------------------------
295//
296// The flag setters are to be used ONLY for Monte-Carlo!!
297//
298void MHGausEvents::SetGausFitOK(const Bool_t b)
299{
300 b ? SETBIT(fFlags,kGausFitOK) : CLRBIT(fFlags,kGausFitOK);
301
302}
303// -------------------------------------------------------------------
304//
305// The flag setters are to be used ONLY for Monte-Carlo!!
306//
307void MHGausEvents::SetExpFitOK(const Bool_t b)
308{
309
310 b ? SETBIT(fFlags,kExpFitOK) : CLRBIT(fFlags,kExpFitOK);
311}
312
313// -------------------------------------------------------------------
314//
315// The flag setters are to be used ONLY for Monte-Carlo!!
316//
317void MHGausEvents::SetFourierSpectrumOK(const Bool_t b)
318{
319
320 b ? SETBIT(fFlags,kFourierSpectrumOK) : CLRBIT(fFlags,kFourierSpectrumOK);
321}
322
323
324// -------------------------------------------------------------------
325//
326// Create the fourier spectrum using the class MFFT.
327// The result is projected into a histogram and fitted by an exponential
328//
329void MHGausEvents::CreateFourierSpectrum()
330{
331
332 if (fFExpFit)
333 return;
334
335 //
336 // The number of entries HAS to be a potence of 2,
337 // so we can only cut out from the last potence of 2 to the rest.
338 // Another possibility would be to fill everything with
339 // zeros, but that gives a low frequency peak, which we would
340 // have to cut out later again.
341 //
342 // So, we have to live with the possibility that at the end
343 // of the calibration run, something has happened without noticing
344 // it...
345 //
346
347 // This cuts only the non-used zero's, but MFFT will later cut the rest
348 MArray::StripZeros(fEvents);
349
350 MFFT fourier;
351
352 fPowerSpectrum = fourier.PowerSpectrumDensity(&fEvents);
353 fHPowerProbability = ProjectArray(*fPowerSpectrum, fPowerProbabilityBins,
354 "PowerProbability",
355 "Probability of Power occurrance");
356 fHPowerProbability->SetXTitle("P(f)");
357 fHPowerProbability->SetDirectory(NULL);
358 //
359 // First guesses for the fit (should be as close to reality as possible,
360 //
361 const Double_t xmax = fHPowerProbability->GetXaxis()->GetXmax();
362
363 fFExpFit = new TF1("FExpFit","exp([0]-[1]*x)",0.,xmax);
364
365 const Double_t slope_guess = (TMath::Log(fHPowerProbability->GetEntries())+1.)/xmax;
366 const Double_t offset_guess = slope_guess*xmax;
367
368 fFExpFit->SetParameters(offset_guess, slope_guess);
369 fFExpFit->SetParNames("Offset","Slope");
370 fFExpFit->SetParLimits(0,offset_guess/2.,2.*offset_guess);
371 fFExpFit->SetParLimits(1,slope_guess/1.5,1.5*slope_guess);
372 fFExpFit->SetRange(0.,xmax);
373
374 fHPowerProbability->Fit(fFExpFit,"RQL0");
375
376 if (GetExpProb() > fProbLimit)
377 SetExpFitOK(kTRUE);
378
379 //
380 // For the moment, this is the only check, later we can add more...
381 //
382 SetFourierSpectrumOK(IsExpFitOK());
383
384 return;
385}
386
387// -------------------------------------------------------------------
388//
389// Fit fGausHist with a Gaussian after stripping zeros from both ends
390// and rebinned to the number of bins specified in fBinsAfterStripping
391//
392// The fit results are retrieved and stored in class-own variables.
393//
394// A flag IsGausFitOK() is set according to whether the fit probability
395// is smaller or bigger than fProbLimit, whether the NDF is bigger than
396// fNDFLimit and whether results are NaNs.
397//
398Bool_t MHGausEvents::FitGaus(Option_t *option, const Double_t xmin, const Double_t xmax)
399{
400
401 if (IsGausFitOK())
402 return kTRUE;
403
404 //
405 // First, strip the zeros from the edges which contain only zeros and rebin
406 // to about fBinsAfterStripping bins.
407 //
408 // (ATTENTION: The Chisquare method is more sensitive,
409 // the _less_ bins, you have!)
410 //
411 StripZeros(&fHGausHist,fBinsAfterStripping);
412
413 //
414 // Get the fitting ranges
415 //
416 Axis_t rmin = (xmin==0.) && (xmax==0.) ? fHGausHist.GetBinCenter(fHGausHist.GetXaxis()->GetFirst()) : xmin;
417 Axis_t rmax = (xmin==0.) && (xmax==0.) ? fHGausHist.GetBinCenter(fHGausHist.GetXaxis()->GetLast()) : xmax;
418
419 //
420 // First guesses for the fit (should be as close to reality as possible,
421 //
422 const Stat_t entries = fHGausHist.Integral("width");
423 const Double_t mu_guess = fHGausHist.GetBinCenter(fHGausHist.GetMaximumBin());
424 const Double_t sigma_guess = fHGausHist.GetRMS();
425 const Double_t area_guess = entries/TMath::Sqrt(TMath::TwoPi())/sigma_guess;
426
427 fFGausFit = new TF1("GausFit","gaus",rmin,rmax);
428
429 if (!fFGausFit)
430 {
431 *fLog << warn << dbginf << "WARNING: Could not create fit function for Gauss fit" << endl;
432 return kFALSE;
433 }
434
435 fFGausFit->SetParameters(area_guess,mu_guess,sigma_guess);
436 fFGausFit->SetParNames("Area","#mu","#sigma");
437 fFGausFit->SetParLimits(0,0.,area_guess*1.5);
438 fFGausFit->SetParLimits(1,rmin,rmax);
439 fFGausFit->SetParLimits(2,0.,rmax-rmin);
440 fFGausFit->SetRange(rmin,rmax);
441
442 fHGausHist.Fit(fFGausFit,option);
443
444
445 fMean = fFGausFit->GetParameter(1);
446 fSigma = fFGausFit->GetParameter(2);
447 fMeanErr = fFGausFit->GetParError(1);
448 fSigmaErr = fFGausFit->GetParError(2);
449 fProb = fFGausFit->GetProb();
450 //
451 // The fit result is accepted under condition:
452 // 1) The results are not nan's
453 // 2) The NDF is not smaller than fNDFLimit (5)
454 // 3) The Probability is greater than fProbLimit (default 0.001 == 99.9%)
455 //
456 if ( TMath::IsNaN(fMean)
457 || TMath::IsNaN(fMeanErr)
458 || TMath::IsNaN(fProb)
459 || TMath::IsNaN(fSigma)
460 || TMath::IsNaN(fSigmaErr)
461 || fFGausFit->GetNDF() < fNDFLimit
462 || fProb < fProbLimit )
463 return kFALSE;
464
465 SetGausFitOK(kTRUE);
466 return kTRUE;
467}
468
469// -----------------------------------------------------------------------------------
470//
471// A default print
472//
473void MHGausEvents::Print(const Option_t *o) const
474{
475
476 *fLog << all << endl;
477 *fLog << all << "Results of the Gauss Fit: " << endl;
478 *fLog << all << "Mean: " << GetMean() << endl;
479 *fLog << all << "Sigma: " << GetSigma() << endl;
480 *fLog << all << "Chisquare: " << GetChiSquare() << endl;
481 *fLog << all << "DoF: " << GetNdf() << endl;
482 *fLog << all << "Probability: " << GetProb() << endl;
483 *fLog << all << endl;
484
485}
486
487// ----------------------------------------------------------------------------------
488//
489// Create a graph to display the array fEvents
490// If the variable fEventFrequency is set, the x-axis is transformed into real time.
491//
492void MHGausEvents::CreateGraphEvents()
493{
494
495 MArray::StripZeros(fEvents);
496
497 const Int_t n = fEvents.GetSize();
498
499 fGraphEvents = new TGraph(n,CreateXaxis(n),fEvents.GetArray());
500 fGraphEvents->SetTitle("Evolution of Events with time");
501 fGraphEvents->GetXaxis()->SetTitle((fEventFrequency) ? "Time [s]" : "Event Nr.");
502}
503
504// ----------------------------------------------------------------------------------
505//
506// Create a graph to display the array fPowerSpectrum
507// If the variable fEventFrequency is set, the x-axis is transformed into real frequency.
508//
509void MHGausEvents::CreateGraphPowerSpectrum()
510{
511
512 MArray::StripZeros(*fPowerSpectrum);
513
514 const Int_t n = fPowerSpectrum->GetSize();
515
516 fGraphPowerSpectrum = new TGraph(n,CreateXaxis(n),fPowerSpectrum->GetArray());
517 fGraphPowerSpectrum->SetTitle("Power Spectrum Density");
518 fGraphPowerSpectrum->GetXaxis()->SetTitle((fEventFrequency) ? "Frequency [Hz]" : "Frequency");
519 fGraphPowerSpectrum->GetYaxis()->SetTitle("P(f)");
520}
521
522// -----------------------------------------------------------------------------
523//
524// Create the x-axis for the graph
525//
526Float_t *MHGausEvents::CreateXaxis(Int_t n)
527{
528
529 Float_t *xaxis = new Float_t[n];
530
531 if (fEventFrequency)
532 for (Int_t i=0;i<n;i++)
533 xaxis[i] = (Float_t)i/fEventFrequency;
534 else
535 for (Int_t i=0;i<n;i++)
536 xaxis[i] = (Float_t)i;
537
538 return xaxis;
539
540}
541
542// -----------------------------------------------------------------------------
543//
544// Default draw:
545//
546// The following options can be chosen:
547//
548// "EVENTS": displays a TGraph of the array fEvents
549// "FOURIER": display a TGraph of the fourier transform of fEvents
550// displays the projection of the fourier transform with the fit
551//
552void MHGausEvents::Draw(const Option_t *opt)
553{
554
555 TVirtualPad *pad = gPad ? gPad : MH::MakeDefCanvas(this,600, 900);
556
557 TString option(opt);
558 option.ToLower();
559
560 Int_t win = 1;
561
562 if (option.Contains("events"))
563 {
564 option.ReplaceAll("events","");
565 win += 1;
566 }
567 if (option.Contains("fourier"))
568 {
569 option.ReplaceAll("fourier","");
570 win += 2;
571 }
572
573 pad->SetTicks();
574 pad->SetBorderMode(0);
575 pad->Divide(1,win);
576 pad->cd(1);
577
578 if (!IsEmpty())
579 gPad->SetLogy();
580
581 fHGausHist.Draw(opt);
582
583 if (fFGausFit)
584 {
585 fFGausFit->SetLineColor(IsGausFitOK() ? kGreen : kRed);
586 fFGausFit->Draw("same");
587 }
588 switch (win)
589 {
590 case 2:
591 pad->cd(2);
592 DrawEvents();
593 break;
594 case 3:
595 pad->cd(2);
596 DrawPowerSpectrum(*pad,3);
597 break;
598 case 4:
599 pad->cd(2);
600 DrawEvents();
601 pad->cd(3);
602 DrawPowerSpectrum(*pad,4);
603 break;
604 }
605}
606
607void MHGausEvents::DrawEvents()
608{
609
610 if (!fGraphEvents)
611 CreateGraphEvents();
612
613 fGraphEvents->SetBit(kCanDelete);
614 fGraphEvents->SetTitle("Events with time");
615 fGraphEvents->Draw("AL");
616
617}
618
619
620void MHGausEvents::DrawPowerSpectrum(TVirtualPad &pad, Int_t i)
621{
622
623 if (fPowerSpectrum)
624 {
625 if (!fGraphPowerSpectrum)
626 CreateGraphPowerSpectrum();
627
628 fGraphPowerSpectrum->Draw("AL");
629 fGraphPowerSpectrum->SetBit(kCanDelete);
630 }
631
632 pad.cd(i);
633
634 if (fHPowerProbability && fHPowerProbability->GetEntries() > 0)
635 {
636 gPad->SetLogy();
637 fHPowerProbability->Draw();
638 if (fFExpFit)
639 {
640 fFExpFit->SetLineColor(IsExpFitOK() ? kGreen : kRed);
641 fFExpFit->Draw("same");
642 }
643 }
644}
645
646
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