source: trunk/MagicSoft/Mars/manalysis/MPadSchweizer.cc@ 1895

Last change on this file since 1895 was 1885, checked in by wittek, 22 years ago
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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): Robert Wagner <mailto:magicsoft@rwagner.de> 10/2002
19! Wolfgang Wittek <mailto:wittek@mppmu.mpg.de> 02/2003
20!
21! Copyright: MAGIC Software Development, 2000-2003
22!
23!
24\* ======================================================================== */
25
26/////////////////////////////////////////////////////////////////////////////
27// //
28// MPadSchweizer //
29// //
30// This task applies padding such that for a given pixel and for a given //
31// Theta bin the resulting distribution of the pedestal sigma is identical//
32// to the distributions given by fHSigmaPixTheta and fHDiffPixTheta. //
33// //
34// The number of photons, its error and the pedestal sigmas are altered. //
35// On average, the number of photons added is zero. //
36// //
37// The formulas used can be found in Thomas Schweizer's Thesis, //
38// Section 2.2.1 //
39// //
40// There are 2 options for the padding : //
41// //
42// 1) fPadFlag = 1 : //
43// Generate first a Sigmabar using the 2D-histogram Sigmabar vs. Theta //
44// (fHSigmaTheta). Then generate a pedestal sigma for each pixel using //
45// the 3D-histogram Theta, pixel no., Sigma^2-Sigmabar^2 //
46// (fHDiffPixTheta). //
47// //
48// This is the preferred option as it takes into account the //
49// correlations between the Sigma of a pixel and Sigmabar. //
50// //
51// 2) fPadFlag = 2 : //
52// Generate a pedestal sigma for each pixel using the 3D-histogram //
53// Theta, pixel no., Sigma (fHSigmaPixTheta). //
54// //
55// //
56// The padding has to be done before the image cleaning because the //
57// image cleaning depends on the pedestal sigmas. //
58// //
59// //
60// This implementation has been tested for CT1 data. For MAGIC some //
61// modifications are necessary. //
62// //
63/////////////////////////////////////////////////////////////////////////////
64#include "MPadSchweizer.h"
65
66#include <stdio.h>
67
68#include "TH1.h"
69#include "TH2.h"
70#include "TH3.h"
71#include "TProfile.h"
72#include "TRandom.h"
73#include "TCanvas.h"
74
75#include "MBinning.h"
76#include "MSigmabar.h"
77#include "MMcEvt.hxx"
78#include "MLog.h"
79#include "MLogManip.h"
80#include "MParList.h"
81#include "MGeomCam.h"
82#include "MCerPhotPix.h"
83#include "MCerPhotEvt.h"
84#include "MPedestalPix.h"
85
86ClassImp(MPadSchweizer);
87
88// --------------------------------------------------------------------------
89//
90// Default constructor.
91//
92MPadSchweizer::MPadSchweizer(const char *name, const char *title,
93 TH2D *fHist2, TH3D *fHist3, TH3D *fHist3Diff) :
94 fRunType(0), fGroup(0)
95{
96 fName = name ? name : "MPadSchweizer";
97 fTitle = title ? title : "Task for the padding (Schweizer)";
98
99 fHSigmaTheta = fHist2;
100 fHSigmaPixTheta = fHist3;
101 fHDiffPixTheta = fHist3Diff;
102
103 fHSigmaTheta->SetDirectory(NULL);
104 fHSigmaPixTheta->SetDirectory(NULL);
105 fHDiffPixTheta->SetDirectory(NULL);
106
107 Print();
108}
109
110// --------------------------------------------------------------------------
111//
112// Destructor.
113//
114MPadSchweizer::~MPadSchweizer()
115{
116 //nothing yet
117}
118
119// --------------------------------------------------------------------------
120//
121// Set the option for the padding
122//
123void MPadSchweizer::SetPadFlag(Int_t padflag)
124{
125 fPadFlag = padflag;
126 *fLog << "MPadSchweizer::SetPadFlag(); choose option " << fPadFlag << endl;
127}
128
129// --------------------------------------------------------------------------
130//
131// Set the pointers and prepare the histograms
132//
133Bool_t MPadSchweizer::PreProcess(MParList *pList)
134{
135 fRnd = new TRandom3(0);
136
137 fMcEvt = (MMcEvt*)pList->FindObject("MMcEvt");
138 if (!fMcEvt)
139 {
140 *fLog << err << dbginf << "MMcEvt not found... aborting." << endl;
141 return kFALSE;
142 }
143
144 fPed = (MPedestalCam*)pList->FindObject("MPedestalCam");
145 if (!fPed)
146 {
147 *fLog << dbginf << "MPedestalCam not found... aborting." << endl;
148 return kFALSE;
149 }
150
151 fCam = (MGeomCam*)pList->FindObject("MGeomCam");
152 if (!fCam)
153 {
154 *fLog << dbginf << "MGeomCam not found (no geometry information available)... aborting." << endl;
155 return kFALSE;
156 }
157
158 fEvt = (MCerPhotEvt*)pList->FindObject("MCerPhotEvt");
159 if (!fEvt)
160 {
161 *fLog << dbginf << "MCerPhotEvt not found... aborting." << endl;
162 return kFALSE;
163 }
164
165 fSigmabar = (MSigmabar*)pList->FindCreateObj("MSigmabar");
166 if (!fSigmabar)
167 {
168 *fLog << dbginf << "MSigmabar not found... aborting." << endl;
169 return kFALSE;
170 }
171
172 // Get Theta Binning
173 MBinning* binstheta = (MBinning*)pList->FindObject("BinningTheta");
174 if (!binstheta)
175 {
176 *fLog << err << dbginf << "BinningTheta not found... aborting." << endl;
177 return kFALSE;
178 }
179
180 // Get Sigma Binning
181 MBinning* binssigma = (MBinning*)pList->FindObject("BinningSigmabar");
182 if (!binssigma)
183 {
184 *fLog << err << dbginf << "BinningSigmabar not found... aborting." << endl;
185 return kFALSE;
186 }
187
188 // Get binning for (sigma^2-sigmabar^2)
189 MBinning* binsdiff = (MBinning*)pList->FindObject("BinningDiffsigma2");
190 if (!binsdiff)
191 {
192 *fLog << err << dbginf << "BinningDiffsigma2 not found... aborting." << endl;
193 return kFALSE;
194 }
195
196 // Get binning for pixel number
197 UInt_t npix = fPed->GetSize();
198 MBinning binspix("BinningPixel");
199 MBinning* binspixel = &binspix;
200 binspixel->SetEdges(npix, -0.5, ((float)npix)-0.5 );
201
202
203 //--------------------------------------------------------------------
204 // histograms for checking the padding
205 //
206 // plot pedestal sigmas
207 fHSigmaPedestal = new TH2D("SigPed","Sigma: after vs. before padding",
208 100, 0.0, 5.0, 100, 0.0, 5.0);
209 fHSigmaPedestal->SetXTitle("orig. Pedestal sigma");
210 fHSigmaPedestal->SetYTitle("padded Pedestal sigma");
211
212 // plot no.of photons (before vs. after padding)
213 fHPhotons = new TH2D("Photons","Photons: after vs.before padding",
214 100, -10.0, 90.0, 100, -10, 90);
215 fHPhotons->SetXTitle("no.of photons before padding");
216 fHPhotons->SetYTitle("no.of photons after padding");
217
218 // plot of added NSB
219 fHNSB = new TH1D("NSB","Distribution of added NSB", 100, -10.0, 10.0);
220 fHNSB->SetXTitle("no.of added NSB photons");
221 fHNSB->SetYTitle("no.of pixels");
222
223 fHSigbarTheta = new TH2D();
224 fHSigbarTheta->SetNameTitle("fHSigmabar",
225 "2D : Sigmabar, \\Theta (after padding)");
226 MH::SetBinning(fHSigbarTheta, binstheta, binssigma);
227 fHSigbarTheta->SetXTitle("Theta");
228 fHSigbarTheta->SetYTitle("Sigmabar");
229
230 fHSigPixTh = new TH3D();
231 fHSigPixTh->SetNameTitle("fHSigPixTh","3D: \\Theta, pixel no., Sigma (after padding)");
232 MH::SetBinning(fHSigPixTh, binstheta, binspixel, binssigma);
233 fHSigPixTh->SetXTitle("\\Theta [\\circ]");
234 fHSigPixTh->SetYTitle("pixel number");
235 fHSigPixTh->SetZTitle("Sigma");
236
237 fHDiffPixTh = new TH3D();
238 fHDiffPixTh->SetNameTitle("fHDiffPixTh","3D: \\Theta, pixel no., Sigma^2-Sigmabar^2 (after padding)");
239 MH::SetBinning(fHDiffPixTh, binstheta, binspixel, binsdiff);
240 fHDiffPixTh->SetXTitle("\\Theta [\\circ]");
241 fHDiffPixTh->SetYTitle("pixel number");
242 fHDiffPixTh->SetZTitle("Sigma^2-Sigmabar^2");
243
244 //--------------------------------------------------------------------
245
246 memset(fErrors, 0, sizeof(fErrors));
247
248 return kTRUE;
249}
250
251// --------------------------------------------------------------------------
252//
253// Do the Padding
254// idealy the events to be padded should have been generated without NSB
255//
256Bool_t MPadSchweizer::Process()
257{
258 //*fLog << "Entry MPadSchweizer::Process();" << endl;
259
260 Int_t rc;
261
262 const UInt_t npix = fEvt->GetNumPixels();
263
264 Double_t SigbarOld;
265
266 //*fLog << "before padding : " << endl;
267 //SigbarOld = fSigmabar->Calc(*fCam, *fPed, *fEvt);
268 //fSigmabar->Print("");
269
270
271 //$$$$$$$$$$$$$$$$$$$$$$$$$$
272 // to simulate the situation that before the padding the NSB and
273 // electronic noise are zero : set Sigma = 0 for all pixels
274 //for (UInt_t i=0; i<npix; i++)
275 //{
276 // MCerPhotPix &pix = fEvt->operator[](i);
277 // Int_t j = pix.GetPixId();
278
279 // MPedestalPix &ppix = fPed->operator[](j);
280 // ppix.SetMeanRms(0.0);
281 //}
282 //$$$$$$$$$$$$$$$$$$$$$$$$$$
283
284 //-------------------------------------------
285 // Calculate average sigma of the event
286 //
287 SigbarOld = fSigmabar->Calc(*fCam, *fPed, *fEvt);
288 //fSigmabar->Print("");
289
290 if (SigbarOld > 0.0)
291 {
292 //*fLog << "MPadSchweizer::Process(); Sigmabar of event to be padded is > 0 : "
293 // << SigbarOld << ". Stop event loop " << endl;
294 // input data should have Sigmabar = 0; stop event loop
295
296 rc = 1;
297 fErrors[rc]++;
298 return kCONTINUE;
299 }
300
301 Double_t Theta = kRad2Deg*fMcEvt->GetTelescopeTheta();
302 // *fLog << "Theta = " << Theta << endl;
303
304
305 //-------------------------------------------
306 // for the current Theta,
307 // generate a Sigmabar according to the histogram fHSigmaTheta
308 //
309 Double_t Sigmabar;
310 Int_t binNumber = fHSigmaTheta->GetXaxis()->FindBin(Theta);
311
312 if ( binNumber < 1 || binNumber > fHSigmaTheta->GetNbinsX() )
313 {
314 *fLog << "MPadSchweizer::Process(); binNumber out of range : Theta, binNumber = "
315 << Theta << ", " << binNumber << "; Skip event " << endl;
316 // event cannot be padded; skip event
317
318 rc = 2;
319 fErrors[rc]++;
320 return kCONTINUE;
321 }
322 else
323 {
324 TH1D* fHSigma =
325 fHSigmaTheta->ProjectionY("", binNumber, binNumber, "");
326 if ( fHSigma->GetEntries() == 0.0 )
327 {
328 *fLog << "MPadSchweizer::Process(); projection for Theta bin "
329 << binNumber << " has no entries; Skip event " << endl;
330 // event cannot be padded; skip event
331 delete fHSigma;
332
333 rc = 3;
334 fErrors[rc]++;
335 return kCONTINUE;
336 }
337 else
338 {
339 Sigmabar = fHSigma->GetRandom();
340
341 //*fLog << "Theta, bin number = " << Theta << ", " << binNumber
342 // << ", Sigmabar = " << Sigmabar << endl;
343 }
344 delete fHSigma;
345 }
346
347
348 //-------------------------------------------
349
350 //*fLog << "MPadSchweizer::Process(); SigbarOld, Sigmabar = "
351 // << SigbarOld << ", "<< Sigmabar << endl;
352
353 // Skip event if target Sigmabar is <= SigbarOld
354 if (Sigmabar <= SigbarOld)
355 {
356 *fLog << "MPadSchweizer::Process(); target Sigmabar is less than SigbarOld : "
357 << Sigmabar << ", " << SigbarOld << ", Skip event" << endl;
358
359 rc = 4;
360 fErrors[rc]++;
361 return kCONTINUE;
362 }
363
364
365 //-------------------------------------------
366 //
367 // Calculate average number of NSB photons to be added (lambdabar)
368 // from the value of Sigmabar,
369 // - making assumptions about the average electronic noise (elNoise2) and
370 // - using a fixed value (F2excess) for the excess noise factor
371
372 Double_t elNoise2; // [photons]
373 Double_t F2excess = 1.3;
374 Double_t lambdabar; // [photons]
375
376
377 Int_t binTheta = fHDiffPixTheta->GetXaxis()->FindBin(Theta);
378 if (binTheta != binNumber)
379 {
380 cout << "The binnings of the 2 histograms are not identical; aborting"
381 << endl;
382 return kERROR;
383 }
384
385 // Get RMS of (Sigma^2-Sigmabar^2) in this Theta bin.
386 // The average electronic noise (to be added) has to be well above this RMS,
387 // otherwise the electronic noise of an individual pixel (elNoise2Pix)
388 // may become negative
389 TH1D* fHNoise = fHDiffPixTheta->ProjectionZ("", binTheta, binTheta,
390 0, 9999, "");
391 Double_t RMS = fHNoise->GetRMS(1);
392 delete fHNoise;
393 elNoise2 = TMath::Min(RMS, Sigmabar*Sigmabar - SigbarOld*SigbarOld);
394 //*fLog << "elNoise2 = " << elNoise2 << endl;
395
396 lambdabar = (Sigmabar*Sigmabar - SigbarOld*SigbarOld - elNoise2)
397 / F2excess;
398 // This value of lambdabar is the same for all pixels;
399 // note that lambdabar is normalized to the area of pixel 0
400
401
402 //---------- start loop over pixels ---------------------------------
403 // do the padding for each pixel
404 //
405 // pad only pixels - which are used (before image cleaning)
406 // - and for which the no.of photons is != 0.0
407 //
408 Double_t Sig = 0.0;
409 Double_t Sigma2 = 0.0;
410 Double_t Diff = 0.0;
411 Double_t addSig2 = 0.0;
412 Double_t elNoise2Pix = 0.0;
413
414
415 for (UInt_t i=0; i<npix; i++)
416 {
417 MCerPhotPix &pix = fEvt->operator[](i);
418 if ( !pix.IsPixelUsed() )
419 continue;
420
421 if ( pix.GetNumPhotons() == 0.0)
422 {
423 *fLog << "MPadSchweizer::Process(); no.of photons is 0 for used pixel"
424 << endl;
425 continue;
426 }
427
428 Int_t j = pix.GetPixId();
429 Double_t Area = fCam->GetPixRatio(j);
430
431 MPedestalPix &ppix = fPed->operator[](j);
432 Double_t oldsigma = ppix.GetMeanRms();
433
434 //---------------------------------
435 // throw the Sigma for this pixel
436 //
437 Int_t binPixel = fHDiffPixTheta->GetYaxis()->FindBin( (Double_t)j );
438
439 Int_t count;
440 Int_t OK;
441 TH1D* fHDiff;
442 TH1D* fHSig;
443
444 switch (fPadFlag)
445 {
446 case 1 :
447 // throw the Sigma for this pixel from the distribution fHDiffPixTheta
448 fHDiff =
449 fHDiffPixTheta->ProjectionZ("", binTheta, binTheta,
450 binPixel, binPixel, "");
451 if ( fHDiff->GetEntries() == 0.0 )
452 {
453 *fLog << "MPadSchweizer::Process(); projection for Theta bin "
454 << binTheta << " and pixel bin " << binPixel
455 << " has no entries; aborting " << endl;
456
457 rc = 5;
458 fErrors[rc]++;
459 return kCONTINUE;
460 }
461
462 count = 0;
463 OK = 0;
464 for (Int_t m=0; m<20; m++)
465 {
466 count += 1;
467 Diff = fHDiff->GetRandom();
468 // the following condition ensures that elNoise2Pix > 0.0
469 if ( (Diff+Sigmabar*Sigmabar-oldsigma*oldsigma/Area-
470 lambdabar*F2excess) > 0.0 )
471 {
472 OK = 1;
473 break;
474 }
475 }
476 if (OK == 0)
477 {
478 *fLog << "Theta, j, count, Sigmabar, Diff = " << Theta << ", "
479 << j << ", " << count << ", " << Sigmabar << ", "
480 << Diff << endl;
481 Diff = lambdabar*F2excess + oldsigma*oldsigma/Area
482 - Sigmabar*Sigmabar;
483 }
484 delete fHDiff;
485 Sigma2 = Diff + Sigmabar*Sigmabar;
486 break;
487
488 case 2 :
489 // throw the Sigma for this pixel from the distribution fHSigmaPixTheta
490 fHSig =
491 fHSigmaPixTheta->ProjectionZ("", binTheta, binTheta,
492 binPixel, binPixel, "");
493 if ( fHSig->GetEntries() == 0.0 )
494 {
495 *fLog << "MPadSchweizer::Process(); projection for Theta bin "
496 << binTheta << " and pixel bin " << binPixel
497 << " has no entries; aborting " << endl;
498
499 rc = 6;
500 fErrors[rc]++;
501 return kCONTINUE;
502 }
503
504 count = 0;
505 OK = 0;
506 for (Int_t m=0; m<20; m++)
507 {
508 count += 1;
509 Sig = fHSig->GetRandom();
510 Sigma2 = Sig*Sig/Area;
511 // the following condition ensures that elNoise2Pix > 0.0
512 if ( (Sigma2-oldsigma*oldsigma/Area-lambdabar*F2excess) > 0.0 )
513 {
514 OK = 1;
515 break;
516 }
517 }
518 if (OK == 0)
519 {
520 *fLog << "Theta, j, count, Sigmabar, Sig = " << Theta << ", "
521 << j << ", " << count << ", " << Sigmabar << ", "
522 << Sig << endl;
523 Sigma2 = lambdabar*F2excess + oldsigma*oldsigma/Area;
524 }
525 delete fHSig;
526 break;
527 }
528
529 //---------------------------------
530 // get the additional sigma^2 for this pixel (due to the padding)
531 addSig2 = Sigma2*Area - oldsigma*oldsigma;
532
533
534 //---------------------------------
535 // get the additional electronic noise for this pixel
536 elNoise2Pix = addSig2 - lambdabar*F2excess*Area;
537
538
539 //---------------------------------
540 // throw actual number of additional NSB photons (NSB)
541 // and its RMS (sigmaNSB)
542 Double_t NSB0 = fRnd->Poisson(lambdabar*Area);
543 Double_t arg = NSB0*(F2excess-1.0) + elNoise2Pix;
544 Double_t sigmaNSB0;
545
546 if (arg >= 0.0)
547 {
548 sigmaNSB0 = sqrt( arg );
549 }
550 else
551 {
552 *fLog << "MPadSchweizer::Process(); argument of sqrt < 0.0 : "
553 << arg << endl;
554 sigmaNSB0 = 0.0000001;
555 }
556
557
558 //---------------------------------
559 // smear NSB0 according to sigmaNSB0
560 // and subtract lambdabar because of AC coupling
561 Double_t NSB = fRnd->Gaus(NSB0, sigmaNSB0) - lambdabar*Area;
562
563 //---------------------------------
564
565 // add additional NSB to the number of photons
566 Double_t oldphotons = pix.GetNumPhotons();
567 Double_t newphotons = oldphotons + NSB;
568 pix.SetNumPhotons( newphotons );
569
570 fHNSB->Fill( NSB/sqrt(Area) );
571 fHPhotons->Fill( newphotons/sqrt(Area), oldphotons/sqrt(Area) );
572
573
574 // error: add sigma of padded noise quadratically
575 Double_t olderror = pix.GetErrorPhot();
576 Double_t newerror = sqrt( olderror*olderror + addSig2 );
577 pix.SetErrorPhot( newerror );
578
579
580 Double_t newsigma = sqrt( oldsigma*oldsigma + addSig2 );
581 ppix.SetMeanRms( newsigma );
582
583 fHSigmaPedestal->Fill( oldsigma, newsigma );
584 fHSigPixTh-> Fill( Theta, (Double_t) j, newsigma );
585 }
586 //---------- end of loop over pixels ---------------------------------
587
588 // Calculate Sigmabar again and crosscheck
589
590 Double_t SigbarNew = fSigmabar->Calc(*fCam, *fPed, *fEvt);
591 //*fLog << "after padding : " << endl;
592 //fSigmabar->Print("");
593
594 fHSigbarTheta->Fill( Theta, SigbarNew );
595
596 // this loop is only for filling the histogram fHDiffPixTh
597 for (UInt_t i=0; i<npix; i++)
598 {
599 MCerPhotPix &pix = fEvt->operator[](i);
600 if ( !pix.IsPixelUsed() )
601 continue;
602
603 if ( pix.GetNumPhotons() == 0.0)
604 {
605 *fLog << "MPadSchweizer::Process(); no.of photons is 0 for used pixel"
606 << endl;
607 continue;
608 }
609
610 Int_t j = pix.GetPixId();
611 Double_t Area = fCam->GetPixRatio(j);
612
613 MPedestalPix &ppix = fPed->operator[](j);
614 Double_t newsigma = ppix.GetMeanRms();
615
616 fHDiffPixTh->Fill( Theta, (Double_t) j,
617 newsigma*newsigma/Area-SigbarNew*SigbarNew);
618 }
619
620
621 //*fLog << "Exit MPadSchweizer::Process();" << endl;
622
623 rc = 0;
624 fErrors[rc]++;
625
626 return kTRUE;
627
628}
629
630// --------------------------------------------------------------------------
631//
632//
633Bool_t MPadSchweizer::PostProcess()
634{
635 if (GetNumExecutions() != 0)
636 {
637
638 *fLog << inf << endl;
639 *fLog << GetDescriptor() << " execution statistics:" << endl;
640 *fLog << dec << setfill(' ');
641 *fLog << " " << setw(7) << fErrors[1] << " (" << setw(3)
642 << (int)(fErrors[1]*100/GetNumExecutions())
643 << "%) Evts skipped due to: Sigmabar_old > 0" << endl;
644
645 *fLog << " " << setw(7) << fErrors[2] << " (" << setw(3)
646 << (int)(fErrors[2]*100/GetNumExecutions())
647 << "%) Evts skipped due to: Zenith angle out of range" << endl;
648
649 *fLog << " " << setw(7) << fErrors[3] << " (" << setw(3)
650 << (int)(fErrors[3]*100/GetNumExecutions())
651 << "%) Evts skipped due to: No data for generating Sigmabar" << endl;
652
653 *fLog << " " << setw(7) << fErrors[4] << " (" << setw(3)
654 << (int)(fErrors[4]*100/GetNumExecutions())
655 << "%) Evts skipped due to: Target sigma <= Sigmabar_old" << endl;
656
657 *fLog << " " << setw(7) << fErrors[5] << " (" << setw(3)
658 << (int)(fErrors[5]*100/GetNumExecutions())
659 << "%) Evts skipped due to: No data for generating Sigma^2-Sigmabar^2" << endl;
660
661 *fLog << " " << setw(7) << fErrors[6] << " (" << setw(3)
662 << (int)(fErrors[6]*100/GetNumExecutions())
663 << "%) Evts skipped due to: No data for generating Sigma" << endl;
664
665 *fLog << " " << fErrors[0] << " ("
666 << (int)(fErrors[0]*100/GetNumExecutions())
667 << "%) Evts survived the padding!" << endl;
668 *fLog << endl;
669
670 }
671
672 //---------------------------------------------------------------
673 TCanvas &c = *(MH::MakeDefCanvas("PadSchweizer", "", 900, 1200));
674 c.Divide(3, 4);
675 gROOT->SetSelectedPad(NULL);
676
677
678 c.cd(1);
679 fHSigmaTheta->SetDirectory(NULL);
680 fHSigmaTheta->SetTitle("2D : Sigmabar, \\Theta (reference sample)");
681 fHSigmaTheta->DrawCopy();
682 fHSigmaTheta->SetBit(kCanDelete);
683
684 //c.cd(1);
685 //fHSigmaPixTheta->DrawCopy();
686 //fHSigmaPixTheta->SetBit(kCanDelete);
687
688 c.cd(4);
689 fHSigbarTheta->SetDirectory(NULL);
690 fHSigbarTheta->DrawCopy();
691 fHSigbarTheta->SetBit(kCanDelete);
692
693
694 c.cd(7);
695 fHNSB->SetDirectory(NULL);
696 fHNSB->DrawCopy();
697 fHNSB->SetBit(kCanDelete);
698
699
700 //--------------------------------------------------------------------
701 // draw the 3D histogram : Theta, pixel, Sigma^2-Sigmabar^2
702
703 TH2D *l;
704
705 c.cd(2);
706 l = (TH2D*) ((TH3*)fHDiffPixTh)->Project3D("zx");
707 l->SetDirectory(NULL);
708 l->SetTitle("Sigma^2-Sigmabar^2 vs. \\Theta (all pixels)");
709 l->SetXTitle("\\Theta [\\circ]");
710 l->SetYTitle("Sigma^2-Sigmabar^2");
711
712 l->DrawCopy("box");
713 l->SetBit(kCanDelete);;
714
715 c.cd(5);
716 l = (TH2D*) ((TH3*)fHDiffPixTh)->Project3D("zy");
717 l->SetDirectory(NULL);
718 l->SetTitle("Sigma^2-Sigmabar^2 vs. pixel number (all \\Theta)");
719 l->SetXTitle("pixel");
720 l->SetYTitle("Sigma^2-Sigmabar^2");
721
722 l->DrawCopy("box");
723 l->SetBit(kCanDelete);;
724
725 c.cd(8);
726 ((TH2*)fHDiffPixTh)->DrawCopy();
727
728
729 //--------------------------------------------------------------------
730 // draw the 3D histogram : Theta, pixel, Sigma
731
732 TH2D *k;
733
734 c.cd(3);
735 k = (TH2D*) ((TH3*)fHSigPixTh)->Project3D("zx");
736 k->SetDirectory(NULL);
737 k->SetTitle("Sigma vs. \\Theta (all pixels)");
738 k->SetXTitle("\\Theta [\\circ]");
739 k->SetYTitle("Sigma");
740
741 k->DrawCopy("box");
742 k->SetBit(kCanDelete);
743
744 c.cd(6);
745 k = (TH2D*) ((TH3*)fHSigPixTh)->Project3D("zy");
746 k->SetDirectory(NULL);
747 k->SetTitle("Sigma vs. pixel number (all \\Theta)");
748 k->SetXTitle("pixel");
749 k->SetYTitle("Sigma");
750
751 k->DrawCopy("box");
752 k->SetBit(kCanDelete);;
753
754 c.cd(9);
755 ((TH2*)fHSigPixTh)->DrawCopy();
756
757 //--------------------------------------------------------------------
758
759 c.cd(10);
760 fHSigmaPedestal->SetDirectory(NULL);
761 fHSigmaPedestal->DrawCopy();
762 fHSigmaPedestal->SetBit(kCanDelete);
763
764 c.cd(11);
765 fHPhotons->SetDirectory(NULL);
766 fHPhotons->DrawCopy();
767 fHPhotons->SetBit(kCanDelete);
768
769 //--------------------------------------------------------------------
770
771 return kTRUE;
772}
773
774// --------------------------------------------------------------------------
775
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