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source: trunk/MagicSoft/Mars/mcalib/MCalibrationBlindPix.cc@ 5701

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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	// MCalibrationBlindPix
28	//
29	// Storage container of the fit results of the Blind Pixel signal
30	// (from MHCalibrationChargeBlindPix).
31	//
32	// The Flux is calculated in photons per mm^2 in the camera plane.
33	//
34	// Currently, the following numbers are implemented:
35	// - fArea: 100 mm^2
36	// - Average QE of Blind Pixel:
37	// fQEGreen: 0.154
38	// fQEBlue : 0.226
39	// fQEUV : 0.247
40	// fQECT1 : 0.247
41	// - Average QE Error of Blind Pixel:
42	// fQEGreenErr: 0.015;
43	// fQEBlueErr : 0.02;
44	// fQEUVErr : 0.02;
45	// fQECT1Err : 0.02;
46	// - Attenuation factor Blind Pixel:
47	// fAttGreen : 1.97;
48	// fAttBlue : 1.96;
49	// fAttUV : 1.95;
50	// fAttCT1 : 1.95;
51	//
52	//
53	/////////////////////////////////////////////////////////////////////////////
54	#include "MCalibrationBlindPix.h"
55
56	#include <TH1.h>
57
58	#include "MLog.h"
59	#include "MLogManip.h"
60
61	ClassImp(MCalibrationBlindPix);
62
63	using namespace std;
64
65	const Float_t MCalibrationBlindPix::fgArea = 100;
66	const Float_t MCalibrationBlindPix::fgAttGreen = 1.97;
67	const Float_t MCalibrationBlindPix::fgAttBlue = 1.96;
68	const Float_t MCalibrationBlindPix::fgAttUV = 1.95;
69	const Float_t MCalibrationBlindPix::fgAttCT1 = 1.95;
70	const Float_t MCalibrationBlindPix::fgAttErr = 0.01;
71	const Float_t MCalibrationBlindPix::fgQEGreen = 0.154;
72	const Float_t MCalibrationBlindPix::fgQEBlue = 0.226;
73	const Float_t MCalibrationBlindPix::fgQEUV = 0.247;
74	const Float_t MCalibrationBlindPix::fgQECT1 = 0.247;
75	const Float_t MCalibrationBlindPix::fgQEErrGreen = 0.005;
76	const Float_t MCalibrationBlindPix::fgQEErrBlue = 0.007;
77	const Float_t MCalibrationBlindPix::fgQEErrUV = 0.01;
78	const Float_t MCalibrationBlindPix::fgQEErrCT1 = 0.01;
79	const Float_t MCalibrationBlindPix::fgCollEffGreen = 0.99;
80	const Float_t MCalibrationBlindPix::fgCollEffBlue = 0.93;
81	const Float_t MCalibrationBlindPix::fgCollEffUV = 0.90;
82	const Float_t MCalibrationBlindPix::fgCollEffCT1 = 0.90;
83	const Float_t MCalibrationBlindPix::fgCollEffErr = 0.05;
84
85	// --------------------------------------------------------------------------
86	//
87	// Default Constructor.
88	//
89	// Calls:
90	// - Clear()
91	//
92	// For backward-compatibility reasons, quantum eff., coll. eff. and att.
93	// are intialized from the static members. This should, however, be
94	// overwritten by a class deriving from MCalibrationBlindCam.
95	//
96	MCalibrationBlindPix::MCalibrationBlindPix(const char name, const char title)
97	{
98
99	fName = name ? name : "MCalibrationBlindPix";
100	fTitle = title ? title : "Container of the fit results of the blind pixel";
101
102	Clear();
103
104	fArea = fgArea;
105	fAreaErr = 0.;
106
107	Float_t att[MCalibrationCam::gkNumPulserColors];
108
109	att [ MCalibrationCam::kGREEN ] = fgAttGreen;
110	att [ MCalibrationCam::kBLUE ] = fgAttBlue;
111	att [ MCalibrationCam::kUV ] = fgAttUV;
112	att [ MCalibrationCam::kCT1 ] = fgAttCT1;
113
114	SetAtt(MCalibrationCam::gkNumPulserColors,att);
115
116	Float_t atterr[MCalibrationCam::gkNumPulserColors];
117
118	atterr [ MCalibrationCam::kGREEN ] = fgAttErr;
119	atterr [ MCalibrationCam::kBLUE ] = fgAttErr;
120	atterr [ MCalibrationCam::kUV ] = fgAttErr;
121	atterr [ MCalibrationCam::kCT1 ] = fgAttErr;
122
123	SetAttErr(MCalibrationCam::gkNumPulserColors,atterr);
124
125	Float_t qe[MCalibrationCam::gkNumPulserColors];
126
127	qe [ MCalibrationCam::kGREEN ] = fgQEGreen;
128	qe [ MCalibrationCam::kBLUE ] = fgQEBlue;
129	qe [ MCalibrationCam::kUV ] = fgQEUV;
130	qe [ MCalibrationCam::kCT1 ] = fgQECT1;
131
132	SetQE(MCalibrationCam::gkNumPulserColors,qe);
133
134	Float_t qeerr[MCalibrationCam::gkNumPulserColors];
135
136	qeerr [ MCalibrationCam::kGREEN ] = fgQEErrGreen;
137	qeerr [ MCalibrationCam::kBLUE ] = fgQEErrBlue;
138	qeerr [ MCalibrationCam::kUV ] = fgQEErrUV;
139	qeerr [ MCalibrationCam::kCT1 ] = fgQEErrCT1;
140
141	SetQEErr(MCalibrationCam::gkNumPulserColors,qeerr);
142
143	Float_t colleff[MCalibrationCam::gkNumPulserColors];
144
145	colleff [ MCalibrationCam::kGREEN ] = fgCollEffGreen;
146	colleff [ MCalibrationCam::kBLUE ] = fgCollEffBlue;
147	colleff [ MCalibrationCam::kUV ] = fgCollEffUV;
148	colleff [ MCalibrationCam::kCT1 ] = fgCollEffCT1;
149
150	SetCollEff(MCalibrationCam::gkNumPulserColors,colleff);
151
152	Float_t collefferr[MCalibrationCam::gkNumPulserColors];
153
154	collefferr [ MCalibrationCam::kGREEN ] = fgCollEffErr;
155	collefferr [ MCalibrationCam::kBLUE ] = fgCollEffErr;
156	collefferr [ MCalibrationCam::kUV ] = fgCollEffErr;
157	collefferr [ MCalibrationCam::kCT1 ] = fgCollEffErr;
158
159	SetCollEffErr(MCalibrationCam::gkNumPulserColors,collefferr);
160	}
161
162	// ------------------------------------------------------------------------
163	//
164	// Sets:
165	// - all flags to kFALSE
166	// - all variables to -1.
167	// - the fColor to MCalibrationCam::kNONE
168	//
169	// Calls:
170	// - MCalibrationPix::Clear()
171	//
172	void MCalibrationBlindPix::Clear(Option_t *o)
173	{
174
175	fFluxInsidePlexiglass = -1.;
176	fFluxInsidePlexiglassVar = -1.;
177	fLambda = -1.;
178	fLambdaCheck = -1.;
179	fLambdaVar = -1.;
180	fMu0 = -1.;
181	fMu0Err = -1.;
182	fMu1 = -1.;
183	fMu1Err = -1.;
184	fSigma0 = -1.;
185	fSigma0Err = -1.;
186	fSigma1 = -1.;
187	fSigma1Err = -1.;
188
189	SetOscillating ( kFALSE );
190	SetExcluded ( kFALSE );
191	SetChargeFitValid ( kFALSE );
192	SetPedestalFitOK ( kFALSE );
193	SetSinglePheFitOK ( kFALSE );
194	SetFluxInsidePlexiglassAvailable ( kFALSE );
195
196	SetColor(MCalibrationCam::kNONE);
197
198	MCalibrationPix::Clear();
199	}
200
201	void MCalibrationBlindPix::SetFluxInsidePlexiglassAvailable( const Bool_t b)
202	{
203	b ? SETBIT(fFlags,kFluxInsidePlexiglassAvailable) : CLRBIT(fFlags,kFluxInsidePlexiglassAvailable);
204	}
205
206
207	// --------------------------------------------------------------------------
208	//
209	// Set the Oscillating Bit from outside
210	//
211	void MCalibrationBlindPix::SetOscillating( const Bool_t b)
212	{
213	b ? SETBIT(fFlags,kOscillating) : CLRBIT(fFlags,kOscillating);
214	}
215
216	// -----------------------------------------------------
217	//
218	// copy 'constructor'
219	//
220	void MCalibrationBlindPix::Copy(TObject& object) const
221	{
222
223	MCalibrationBlindPix &pix = (MCalibrationBlindPix&)object;
224
225	//
226	// Copy the data members
227	//
228	pix.fPixId = fPixId;
229	pix.fFlags = fFlags;
230	pix.fArea = fArea;
231	pix.fAreaErr = fAreaErr;
232	pix.fColor = fColor;
233
234	//
235	// Copy arrays
236	//
237	pix.fAtt = fAtt;
238	pix.fAttErr = fAttErr;
239	pix.fQE = fQE;
240	pix.fQEErr = fQEErr;
241	pix.fCollEff = fCollEff;
242	pix.fCollEffErr = fCollEffErr;
243
244	pix.fLambda = fLambda;
245	pix.fLambdaCheck = fLambdaCheck;
246	pix.fLambdaCheckErr = fLambdaCheckErr;
247	pix.fLambdaVar = fLambdaVar;
248	pix.fFluxInsidePlexiglass = fFluxInsidePlexiglass;
249	pix.fFluxInsidePlexiglassVar = fFluxInsidePlexiglassVar;
250	pix.fMu0 = fMu0;
251	pix.fMu0Err = fMu0Err;
252	pix.fMu1 = fMu1;
253	pix.fMu1Err = fMu1Err;
254	pix.fSigma0 = fSigma0;
255	pix.fSigma0Err = fSigma0Err;
256	pix.fSigma1 = fSigma1;
257	pix.fSigma1Err = fSigma1Err;
258
259	}
260
261
262	// --------------------------------------------------------------------------
263	//
264	// Set the ChargeFitValid Bit from outside
265	//
266	void MCalibrationBlindPix::SetChargeFitValid( const Bool_t b)
267	{
268	b ? SETBIT(fFlags,kChargeFitValid) : CLRBIT(fFlags,kChargeFitValid);
269	}
270
271	// --------------------------------------------------------------------------
272	//
273	// Set the PedestalFitValid Bit from outside
274	//
275	void MCalibrationBlindPix::SetPedestalFitOK( const Bool_t b)
276	{
277	b ? SETBIT(fFlags,kPedestalFitOK) : CLRBIT(fFlags,kPedestalFitOK);
278	}
279
280	// --------------------------------------------------------------------------
281	//
282	// Set the SinglePheFitValid Bit from outside
283	//
284	void MCalibrationBlindPix::SetSinglePheFitOK( const Bool_t b)
285	{
286	b ? SETBIT(fFlags,kSinglePheFitOK) : CLRBIT(fFlags,kSinglePheFitOK);
287	}
288
289	// --------------------------------------------------------------------------
290	//
291	// Return -1 if fFluxInsidePlexiglassVar is smaller than 0.
292	// Return square root of fFluxInsidePlexiglassVar
293	//
294	const Float_t MCalibrationBlindPix::GetFluxInsidePlexiglassErr() const
295	{
296	if (fFluxInsidePlexiglassVar < 0.)
297	return -1.;
298
299	return TMath::Sqrt(fFluxInsidePlexiglassVar);
300	}
301
302	// --------------------------------------------------------------------------
303	//
304	// Return -1 if fFluxInsidePlexiglassVar is smaller than 0.
305	// Return -1 if fFluxInsidePlexiglass is 0.
306	// Return fFluxInsidePlexiglassVar / fFluxInsidePlexiglass^2
307	//
308	const Float_t MCalibrationBlindPix::GetFluxInsidePlexiglassRelVar() const
309	{
310	if (fFluxInsidePlexiglassVar < 0.)
311	return -1.;
312
313	if (fFluxInsidePlexiglass == 0.)
314	return -1.;
315
316	return fFluxInsidePlexiglassVar / (fFluxInsidePlexiglass * fFluxInsidePlexiglass) ;
317	}
318
319	// --------------------------------------------------------------------------
320	//
321	// Return -1 if fLambdaVar is smaller than 0.
322	// Return square root of fLambdaVar
323	//
324	const Float_t MCalibrationBlindPix::GetLambdaErr() const
325	{
326	if (fLambdaVar < 0.)
327	return -1.;
328
329	return TMath::Sqrt(fLambdaVar);
330	}
331
332	// --------------------------------------------------------------------------
333	//
334	// Return -1 if fLambdaVar is smaller than 0.
335	// Return -1 if fLambda is 0.
336	// Return fLambdaVar / (fLambda * fLambda )
337	//
338	const Float_t MCalibrationBlindPix::GetLambdaRelVar() const
339	{
340	if (fLambdaVar < 0.)
341	return -1.;
342
343	if (fLambda == 0.)
344	return -1.;
345
346	return fLambdaVar / fLambda / fLambda ;
347	}
348
349	// --------------------------------------------------------------------------
350	//
351	// Return fAreaErr^2 / (fArea^2 )
352	//
353	const Float_t MCalibrationBlindPix::GetAreaRelVar() const
354	{
355	return fAreaErr*fAreaErr/fArea/fArea;
356	}
357
358
359	// --------------------------------------------------------------------------
360	//
361	// Return TMath::Power(10,fAtt[fColor])
362	//
363	const Float_t MCalibrationBlindPix::GetAtt() const
364	{
365	return TMath::Power(10,fAtt[fColor]);
366	}
367
368	// --------------------------------------------------------------------------
369	//
370	// Return -1 if fAttErr[fColor] is smaller than 0.
371	// Error of TMath::Power(10,fAtt[fColor]) = TMath::Power(10,fAtt[fColor])ln(10.)fAttErr[fColor]
372	// Return fAttErr^2 / (fAtt^2 )
373	//
374	const Float_t MCalibrationBlindPix::GetAttRelVar() const
375	{
376
377	const Float_t err = fAttErr[fColor];
378
379	if (err < 0.)
380	return -1.;
381
382	return errerr2.3;
383	}
384
385	// --------------------------------------------------------------------------
386	//
387	// Return fQE[fColor]
388	//
389	const Float_t MCalibrationBlindPix::GetQE() const
390	{
391	return fQE[fColor];
392	}
393
394	// --------------------------------------------------------------------------
395	//
396	// Return -1 if fQEErr[fColor] is smaller than 0.
397	// Return fQEErr^2 / (fQE^2 )
398	//
399	const Float_t MCalibrationBlindPix::GetQERelVar() const
400	{
401
402	if (fQEErr[fColor] < 0.)
403	return -1.;
404
405	return fQEErr[fColor]* fQEErr[fColor] / GetQE() / GetQE();
406	}
407
408	// --------------------------------------------------------------------------
409	//
410	// Return fCollEff[fColor]
411	//
412	const Float_t MCalibrationBlindPix::GetCollEff() const
413	{
414	return fCollEff[fColor];
415	}
416
417	// --------------------------------------------------------------------------
418	//
419	// Return -1 if fCollEffErr[fColor] is smaller than 0.
420	// Return fCollEffErr^2 / (fCollEff^2 )
421	//
422	const Float_t MCalibrationBlindPix::GetCollEffRelVar() const
423	{
424
425	if (fCollEffErr[fColor] < 0.)
426	return -1.;
427
428	return fCollEffErr[fColor]* fCollEffErr[fColor] / GetCollEff() / GetCollEff();
429	}
430
431	// --------------------------------------------------------------------------
432	//
433	// Test bit kChargeFitValid
434	//
435	const Bool_t MCalibrationBlindPix::IsChargeFitValid() const
436	{
437	return TESTBIT(fFlags,kChargeFitValid);
438	}
439
440	// --------------------------------------------------------------------------
441	//
442	// Test bit kOscillating
443	//
444	const Bool_t MCalibrationBlindPix::IsOscillating() const
445	{
446	return TESTBIT(fFlags,kOscillating);
447	}
448
449	// --------------------------------------------------------------------------
450	//
451	// Test bit kPedestalFitValid
452	//
453	const Bool_t MCalibrationBlindPix::IsPedestalFitOK() const
454	{
455	return TESTBIT(fFlags,kPedestalFitOK);
456	}
457
458	// --------------------------------------------------------------------------
459	//
460	// Test bit kSinglePheFitValid
461	//
462	const Bool_t MCalibrationBlindPix::IsSinglePheFitOK() const
463	{
464	return TESTBIT(fFlags,kSinglePheFitOK);
465	}
466
467	// --------------------------------------------------------------------------
468	//
469	// Test bit kFluxInsidePlexiglassAvailable
470	//
471	const Bool_t MCalibrationBlindPix::IsFluxInsidePlexiglassAvailable() const
472	{
473	return TESTBIT(fFlags,kFluxInsidePlexiglassAvailable);
474	}
475
476
477	// --------------------------------------------------------------------------
478	//
479	// Return kFALSE if IsChargeFitValid() is kFALSE
480	//
481	// Calculate fFluxInsidePlexiglass with the formula:
482	// - fFluxInsidePlexiglass = fLambda
483	// / GetCollEff()
484	// / GetQE()
485	// * GetAtt()
486	// / fArea
487	// - fFluxInsidePlexiglassVar = sqrt( fLambdaVar / ( fLambda * fLambda )
488	// + GetQERelVar()
489	// + GetCollEffRelVar()
490	// + GetAttRelVar()
491	// ) * fFluxInsidePlexiglass * * fFluxInsidePlexiglass
492	//
493	// If the fFluxInsidePlexiglass is smaller than 0., return kFALSE
494	// If the Variance is smaller than 0., return kFALSE
495	//
496	// SetFluxInsidePlexiglassAvailable() and return kTRUE
497	//
498	Bool_t MCalibrationBlindPix::CalcFluxInsidePlexiglass()
499	{
500
501	if (IsChargeFitValid())
502	return kFALSE;
503
504
505	//
506	// Start calculation of number of photons
507	// The blind pixel has exactly 100 mm^2 area (with negligible error),
508	//
509	fFluxInsidePlexiglass = fLambda / GetQE() * GetAtt() / GetCollEff() / fArea;
510
511	if (fFluxInsidePlexiglass < 0.)
512	return kFALSE;
513
514	fFluxInsidePlexiglassVar = GetLambdaRelVar() + GetQERelVar() + GetAttRelVar() + GetCollEffRelVar() + GetAreaRelVar();
515
516	//
517	// Finish calculation of errors -> convert from relative variance to absolute variance
518	//
519	fFluxInsidePlexiglassVar = fFluxInsidePlexiglass fFluxInsidePlexiglass;
520
521	if (fFluxInsidePlexiglassVar < 0.)
522	return kFALSE;
523
524	SetFluxInsidePlexiglassAvailable(kTRUE);
525
526	*fLog << inf << GetDescriptor()
527	<< ": BlindPix #" << fPixId << ": Flux [ph/mm^2] inside Plexiglass: "
528	<< Form("%5.3f +- %5.3f",fFluxInsidePlexiglass, GetFluxInsidePlexiglassErr()) << endl;
529
530	return kTRUE;
531	}
532
533	void MCalibrationBlindPix::Print(Option_t *opt) const
534	{
535
536	*fLog << all << GetDescriptor()
537	<< Form("BlindPixel: %3i" ,GetPixId())
538	<< Form(" Lambda: %4.2f +- %4.2f",GetLambda(),GetLambdaErr())
539	<< Form(" Mu0: %4.2f +- %4.2f" ,GetMu0(), GetMu0Err())
540	<< Form(" Mu1: %4.2f +- %4.2f" ,GetMu1(), GetMu1Err())
541	<< Form(" Sigma0: %4.2f +- %4.2f",GetSigma0(),GetSigma0Err())
542	<< Form(" Sigma1: %4.2f +- %4.2f",GetSigma1(),GetSigma1Err())
543	<< endl;
544	*fLog << all
545	<< " Pedestal Fit OK? :" << IsPedestalFitOK()
546	<< Form(" Lambda (Check): %4.2f +- %4.2f",GetLambdaCheck(),GetLambdaCheckErr())
547	<< endl;
548	*fLog << all
549	<< " Flux available? :" << IsFluxInsidePlexiglassAvailable()
550	<< Form(" Flux: %4.2f +- %4.2f",GetFluxInsidePlexiglass(),GetFluxInsidePlexiglassErr())
551	<< endl;
552	}

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