source: trunk/Mars/msimcamera/MSimRandomPhotons.cc@ 10058

Last change on this file since 10058 was 9991, checked in by tbretz, 14 years ago
Changed the checks in MSimRandomPhotons which didn't allow pedestal and calibration runs to be produced
File size: 18.9 KB
Line 
1/* ======================================================================== *\
2!
3! *
4! * This file is part of CheObs, the Modular 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 appears 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): Thomas Bretz, 1/2009 <mailto:tbretz@astro.uni-wuerzburg.de>
19!
20! Copyright: CheObs Software Development, 2000-2009
21!
22!
23\* ======================================================================== */
24
25//////////////////////////////////////////////////////////////////////////////
26//
27// MSimRandomPhotons
28//
29// Simulate poissonian photons. Since the distribution of the arrival time
30// differences of these photons is an exonential we can simulate them
31// using exponentially distributed time differences between two consecutive
32// photons.
33//
34// FIXME: We should add the wavelength distribution.
35//
36// The artificial night sky background rate is calculated as follows:
37//
38// * The photon detection efficiency vs. wavelength of the detector is obtained
39// from "PhotonDetectionEfficiency" of type "MParSpline"
40//
41// * The angular acceptance of the light collectors is obtained
42// from "ConesAngularAcceptance" of type "MParSpline"
43//
44// * The spectral acceptance of the light collectors is obtained
45// from "ConesTransmission" of type "MParSpline"
46//
47// * The reflectivity of the mirrors vs wavelength is obtained
48// from "MirrorReflectivity" of type "MParSpline"
49//
50// The rate is then calculated as
51//
52// R = R0 * Ai * f
53//
54// R0 is the night sky background rate as given in Eckart's paper (divided
55// by the wavelength window). Ai the area of the cones acceptance window,
56// f is given as:
57//
58// f = nm * Min(Ar, sr*d^2)
59//
60// with
61//
62// nm being the integral of the product of the mirror reflectivity, the cone
63// transmission and the photon detection efficiency.
64//
65// d the distance of the focal plane to the mirror
66//
67// Ar is the total reflective area of the reflector
68//
69// sr is the effective solid angle corresponding to the integral of the
70// cones angular acceptance
71//
72// Alternatively, the night-sky background rate can be calculated from
73// a spectrum as given in Fig. 1 (but versus Nanometers) in
74//
75// Chris R. Benn & Sara L. Ellison La Palma Night-Sky Brightness
76//
77// After proper conversion of the units, the rate of the pixel 0
78// is then calculated by
79//
80// rate = f * nsb
81//
82// With nsb
83//
84// nsb = Integral(nsb spectrum * combines efficiencies)
85//
86// and f can be either
87//
88// Eff. angular acceptance Cones (e.g. 20deg) * Cone-Area (mm^2)
89// f = sr * A0
90//
91// or
92//
93// Mirror-Area * Field of view of cones (deg^2)
94// f = Ar * A0;
95//
96//
97// Input Containers:
98// fNameGeomCam [MGeomCam]
99// MPhotonEvent
100// MPhotonStatistics
101// MCorsikaEvtHeader
102// [MCorsikaRunHeader]
103//
104// Output Containers:
105// MPhotonEvent
106// AccidentalPhotonRate [MPedestalCam]
107//
108//////////////////////////////////////////////////////////////////////////////
109#include "MSimRandomPhotons.h"
110
111#include <TRandom.h>
112
113#include "MMath.h" // RndmExp
114
115#include "MLog.h"
116#include "MLogManip.h"
117
118#include "MParList.h"
119
120#include "MGeomCam.h"
121#include "MGeom.h"
122
123#include "MPhotonEvent.h"
124#include "MPhotonData.h"
125
126#include "MPedestalCam.h"
127#include "MPedestalPix.h"
128
129#include "MCorsikaRunHeader.h"
130
131#include "MSpline3.h"
132#include "MParSpline.h"
133#include "MReflector.h"
134
135ClassImp(MSimRandomPhotons);
136
137using namespace std;
138
139// --------------------------------------------------------------------------
140//
141// Default Constructor.
142//
143MSimRandomPhotons::MSimRandomPhotons(const char* name, const char *title)
144 : fGeom(0), fEvt(0), fStat(0), /*fEvtHeader(0),*/ fRunHeader(0),
145 fRates(0), fSimulateWavelength(kFALSE), fNameGeomCam("MGeomCam"),
146 fFileNameNSB("resmc/night-sky-la-palma.txt")
147{
148 fName = name ? name : "MSimRandomPhotons";
149 fTitle = title ? title : "Simulate possonian photons (like NSB or dark current)";
150}
151
152// --------------------------------------------------------------------------
153//
154// Check for the necessary containers
155//
156Int_t MSimRandomPhotons::PreProcess(MParList *pList)
157{
158 fGeom = (MGeomCam*)pList->FindObject(fNameGeomCam, "MGeomCam");
159 if (!fGeom)
160 {
161 *fLog << inf << fNameGeomCam << " [MGeomCam] not found..." << endl;
162
163 fGeom = (MGeomCam*)pList->FindObject("MGeomCam");
164 if (!fGeom)
165 {
166 *fLog << err << "MGeomCam not found... aborting." << endl;
167 return kFALSE;
168 }
169 }
170
171 fEvt = (MPhotonEvent*)pList->FindObject("MPhotonEvent");
172 if (!fEvt)
173 {
174 *fLog << err << "MPhotonEvent not found... aborting." << endl;
175 return kFALSE;
176 }
177
178 fStat = (MPhotonStatistics*)pList->FindObject("MPhotonStatistics");
179 if (!fStat)
180 {
181 *fLog << err << "MPhotonStatistics not found... aborting." << endl;
182 return kFALSE;
183 }
184
185 fRates = (MPedestalCam*)pList->FindCreateObj("MPedestalCam", "AccidentalPhotonRates");
186 if (!fRates)
187 return kFALSE;
188
189 /*
190 fEvtHeader = (MCorsikaEvtHeader*)pList->FindObject("MCorsikaEvtHeader");
191 if (!fEvtHeader)
192 {
193 *fLog << err << "MCorsikaEvtHeader not found... aborting." << endl;
194 return kFALSE;
195 }*/
196
197 fRunHeader = (MCorsikaRunHeader*)pList->FindObject("MCorsikaRunHeader");
198 if (fSimulateWavelength && !fRunHeader)
199 {
200 *fLog << err << "MCorsikaRunHeader not found... aborting." << endl;
201 return kFALSE;
202 }
203
204 MReflector *r = (MReflector*)pList->FindObject("Reflector", "MReflector");
205 if (!r)
206 {
207 *fLog << err << "Reflector [MReflector] not found... aborting." << endl;
208 return kFALSE;
209 }
210
211 const MParSpline *s1 = (MParSpline*)pList->FindObject("PhotonDetectionEfficiency", "MParSpline");
212 const MParSpline *s2 = (MParSpline*)pList->FindObject("ConesTransmission", "MParSpline");
213 const MParSpline *s3 = (MParSpline*)pList->FindObject("MirrorReflectivity", "MParSpline");
214 const MParSpline *s4 = (MParSpline*)pList->FindObject("ConesAngularAcceptance", "MParSpline");
215
216 // Ensure that all efficiencies are at least defined in the raneg of the
217 // photon detection efficiency. We assume that this is the limiting factor
218 // and has to be zero at both ends.
219 if (s2->GetXmin()>s1->GetXmin())
220 {
221 *fLog << err << "ERROR - ConeTransmission range must be defined down to " << s1->GetXmin() << "nm (PhotonDetectionEffciency)." << endl;
222 return kFALSE;
223 }
224 if (s2->GetXmax()<s1->GetXmax())
225 {
226 *fLog << err << "ERROR - ConeTransmission range must be defined up to " << s1->GetXmax() << "nm (PhotonDetectionEffciency)." << endl;
227 return kFALSE;
228 }
229 if (s3->GetXmin()>s1->GetXmin())
230 {
231 *fLog << err << "ERROR - MirrorReflectivity range must be defined down to " << s1->GetXmin() << "nm (PhotonDetectionEffciency)." << endl;
232 return kFALSE;
233 }
234 if (s3->GetXmax()<s1->GetXmax())
235 {
236 *fLog << err << "ERROR - MirrorReflectivity range must be defined up to " << s1->GetXmax() << "nm (PhotonDetectionEffciency)." << endl;
237 return kFALSE;
238 }
239
240 // If the simulated wavelenth range exists and is smaller reduce the
241 // range to it. Later it is checked that at both edges the transmission
242 // is 0. This must be true in both cases: The simulated wavelength range
243 // exceed the PDE or the PDE range exceeds the simulated waveband.
244 const Float_t wmin = fRunHeader && fRunHeader->GetWavelengthMin()>s1->GetXmin() ? fRunHeader->GetWavelengthMin() : s1->GetXmin();
245 const Float_t wmax = fRunHeader && fRunHeader->GetWavelengthMax()<s1->GetXmax() ? fRunHeader->GetWavelengthMax() : s1->GetXmax();
246
247 const Int_t min = TMath::FloorNint(wmin);
248 const Int_t max = TMath::CeilNint(wmax);
249
250 // Multiply all relevant efficiencies to get the total transmission
251 MParSpline eff;
252 eff.SetFunction("1", max-min, min, max);
253
254 eff.Multiply(*s1->GetSpline());
255 eff.Multiply(*s2->GetSpline());
256 eff.Multiply(*s3->GetSpline());
257
258 // Effectively transmitted wavelength band in the simulated range
259 const Double_t nm = eff.GetSpline()->Integral();
260
261 // Angular acceptance of the cones
262 const Double_t sr = s4 && s4->GetSpline() ? s4->GetSpline()->IntegralSolidAngle() : 1;
263
264 {
265 const Double_t d2 = fGeom->GetCameraDist()*fGeom->GetCameraDist();
266 const Double_t conv = fGeom->GetConvMm2Deg()*TMath::DegToRad();
267 const Double_t f1 = TMath::Min(r->GetA()/1e4, sr*d2) * conv*conv;
268
269 // Rate in GHz / mm^2
270 fScale = fFreqNSB * nm * f1; // [GHz/mm^2] efficiency * m^2 *rad^2 *mm^2
271
272 const Double_t freq0 = fScale*(*fGeom)[0].GetA()*1000;
273
274 *fLog << inf << "Resulting Freq. in " << fNameGeomCam << "[0]: " << Form("%.2f", freq0) << "MHz" << endl;
275
276 // FIXME: Scale with the number of pixels
277 if (freq0>1000)
278 {
279 *fLog << err << "ERROR - Frequency exceeds 1GHz, this might leed to too much memory consumption." << endl;
280 return kFALSE;
281 }
282 }
283
284 if (fFileNameNSB.IsNull())
285 return kTRUE;
286
287 // const MMcRunHeader *mcrunheader = (MMcRunHeader*)pList->FindObject("MMcRunHeader");
288 // Set NumPheFromDNSB
289
290 // # Number of photons from the diffuse NSB (nphe / ns 0.1*0.1 deg^2 239 m^2) and
291 // nsb_mean 0.20
292 // Magic pixel: 0.00885361 deg
293 // dnsbpix = 0.2*50/15
294 // ampl = MMcFadcHeader->GetAmplitud()
295 // sqrt(pedrms*pedrms + dnsbpix*ampl*ampl/ratio)
296
297 // Conversion of the y-axis
298 // ------------------------
299 // Double_t ff = 1; // myJy / arcsec^2 per nm
300 // ff *= 1e-6; // Jy / arcsec^2 per nm
301 // ff *= 3600*3600; // Jy / deg^2
302 // ff *= 1./TMath::DegToRad()/TMath::DegToRad(); // Jy/sr = 1e-26J/s/m^2/Hz/sr
303 // ff *= 1e-26; // J/s/m^2/Hz/sr per nm
304
305 const Double_t arcsec2rad = TMath::DegToRad()/3600.;
306 const Double_t f = 1e-32 / (arcsec2rad*arcsec2rad);
307
308 // Read night sky background flux from file
309 MParSpline flux;
310 if (!flux.ReadFile(fFileNameNSB))
311 return kFALSE;
312
313 if (flux.GetXmin()>wmin)
314 {
315 *fLog << err << "ERROR - NSB flux from " << fFileNameNSB << " must be defined down to " << wmin << "nm." << endl;
316 return kFALSE;
317 }
318 if (flux.GetXmax()<wmax)
319 {
320 *fLog << err << "ERROR - NSB flux from " << fFileNameNSB << " must be defined up to " << wmax << "nm." << endl;
321 return kFALSE;
322 }
323
324 MParSpline nsb;
325
326 // Normalization to our units,
327 // conversion from energy flux to photon flux
328 nsb.SetFunction(Form("%.12e/(x*TMath::H())", f), max-min, min, max);
329
330 // multiply night sky background flux with normalization
331 nsb.Multiply(*flux.GetSpline());
332
333 // Multiply with the total transmission
334 nsb.Multiply(*eff.GetSpline());
335
336 // Check if the photon flux is zero at both ends of the NSB
337 if (eff.GetSpline()->Eval(min)>1e-5)
338 {
339 *fLog << warn << "WARNING - Total transmission efficiency at ";
340 *fLog << min << "nm is not zero, but " << nsb.GetSpline()->Eval(min) << "... abort." << endl;
341 }
342 if (eff.GetSpline()->Eval(max)>1e-5)
343 {
344 *fLog << warn << "WARNING - Total transmission efficiency at ";
345 *fLog << max << "nm is not zero, but " << nsb.GetSpline()->Eval(max) << "... abort." << endl;
346 }
347
348 // Check if the photon flux is zero at both ends of the simulated region
349 if (eff.GetSpline()->Eval(wmin)>1e-5)
350 {
351 *fLog << err << "ERROR - Total transmission efficiency at ";
352 *fLog << wmin << "nm is not zero... abort." << endl;
353 *fLog << " PhotonDetectionEfficency: " << s1->GetSpline()->Eval(wmin) << endl;
354 *fLog << " ConeTransmission: " << s2->GetSpline()->Eval(wmin) << endl;
355 *fLog << " MirrorReflectivity: " << s3->GetSpline()->Eval(wmin) << endl;
356 *fLog << " TotalEfficiency: " << eff.GetSpline()->Eval(wmin) << endl;
357 return kFALSE;
358 }
359 if (eff.GetSpline()->Eval(wmax)>1e-5)
360 {
361 *fLog << err << "ERROR - Total transmission efficiency at ";
362 *fLog << wmax << "nm is not zero... abort." << endl;
363 *fLog << " PhotonDetectionEfficency: " << s1->GetSpline()->Eval(wmax) << endl;
364 *fLog << " ConeTransmission: " << s2->GetSpline()->Eval(wmax) << endl;
365 *fLog << " MirrorReflectivity: " << s3->GetSpline()->Eval(wmax) << endl;
366 *fLog << " TotalEfficiency: " << eff.GetSpline()->Eval(wmax) << endl;
367 return kFALSE;
368 }
369
370 // Conversion from m to radians
371 const Double_t conv = fGeom->GetConvMm2Deg()*TMath::DegToRad()*1e3;
372
373 // Angular acceptance of the cones
374 //const Double_t sr = s5.GetSpline()->IntegralSolidAngle(); // sr
375 // Absolute reflector area
376 const Double_t Ar = r->GetA()/1e4; // m^2
377 // Size of the cone's entrance window
378 const Double_t A0 = (*fGeom)[0].GetA()*1e-6; // m^2
379
380 // Rate * m^2 * Solid Angle
381 // -------------------------
382
383 // Angular acceptance Cones (e.g. 20deg) * Cone-Area
384 const Double_t f1 = A0 * sr; // m^2 sr
385
386 // Mirror-Area * Field of view of cones (e.g. 0.1deg)
387 const Double_t f2 = Ar * A0*conv*conv; // m^2 sr
388
389 // FIXME: Calculate the reflectivity of the bottom by replacing
390 // MirrorReflectivity by bottom reflectivity and reflect
391 // and use it to reflect the difference between f1 and f2
392 // if any.
393
394 // Total NSB rate in MHz per m^2 and sr
395 const Double_t rate = nsb.GetSpline()->Integral() * 1e-6;
396
397 *fLog << inf;
398
399 // Resulting rates as if Razmick's constant had been used
400 // *fLog << 1.75e6/(600-300) * f1 * eff.GetSpline()->Integral() << " MHz" << endl;
401 // *fLog << 1.75e6/(600-300) * f2 * eff.GetSpline()->Integral() << " MHz" << endl;
402
403 *fLog << "Conversion factor Fnu: " << f << endl;
404 *fLog << "Total reflective area: " << Form("%.2f", Ar) << " m" << UTF8::kSquare << endl;
405 *fLog << "Acceptance area of cone 0: " << Form("%.2f", A0*1e6) << " mm" << UTF8::kSquare << " = ";
406 *fLog << A0*conv*conv << " sr" << endl;
407 *fLog << "Cones angular acceptance: " << sr << " sr" << endl;
408 *fLog << "ConeArea*ConeSolidAngle (f1): " << f1 << " m^2 sr" << endl;
409 *fLog << "MirrorArea*ConeSkyAngle (f2): " << f2 << " m^2 sr" << endl;
410 *fLog << "Effective. transmission: " << Form("%.1f", nm) << " nm" << endl;
411 *fLog << "NSB freq. in " << fNameGeomCam << "[0] (f1): " << Form("%.2f", rate * f1) << " MHz" << endl;
412 *fLog << "NSB freq. in " << fNameGeomCam << "[0] (f2): " << Form("%.2f", rate * f2) << " MHz" << endl;
413 *fLog << "Using f2." << endl;
414
415 // Scale the rate per mm^2 and to GHz
416 fScale = rate * f2 / (*fGeom)[0].GetA() / 1000;
417
418 // FIXME: Scale with the number of pixels
419 if (rate*f2>1000)
420 {
421 *fLog << err << "ERROR - Frequency exceeds 1GHz, this might leed to too much memory consumption." << endl;
422 return kFALSE;
423 }
424
425 return kTRUE;
426}
427
428Bool_t MSimRandomPhotons::ReInit(MParList *pList)
429{
430 // Overwrite the default set by MGeomApply
431 fRates->Init(*fGeom);
432 return kTRUE;
433}
434
435// --------------------------------------------------------------------------
436//
437// Check for the necessary containers
438//
439Int_t MSimRandomPhotons::Process()
440{
441 // Get array from event container
442 // const Int_t num = fEvt->GetNumPhotons();
443 //
444 // Do not produce pure pedestal events!
445 // if (num==0)
446 // return kTRUE;
447
448 // Get array from event container
449 // FIXME: Use statistics container instead
450 const UInt_t npix = fGeom->GetNumPixels();
451
452 // This is the possible window in which the triggered digitization
453 // may take place.
454 const Double_t start = fStat->GetTimeFirst();
455 const Double_t end = fStat->GetTimeLast();
456
457 // Loop over all pixels
458 for (UInt_t idx=0; idx<npix; idx++)
459 {
460 // Scale the rate with the pixel size.
461 const Double_t rate = fFreqFixed + fScale*(*fGeom)[idx].GetA();
462
463 (*fRates)[idx].SetPedestal(rate);
464
465 // Calculate the average distance between two consequtive photons
466 const Double_t avglen = 1./rate;
467
468 // Start producing photons at time "start"
469 Double_t t = start;
470 while (1)
471 {
472 // Get a random time for the photon.
473 // The differences are exponentially distributed.
474 t += MMath::RndmExp(avglen);
475
476 // Check if we reached the end of the useful time window
477 if (t>end)
478 break;
479
480 // Add a new photon
481 // FIXME: SLOW!
482 MPhotonData &ph = fEvt->Add();
483
484 // Set source to NightSky, time to t and tag to pixel index
485 ph.SetPrimary(MMcEvtBasic::kNightSky);
486 ph.SetWeight();
487 ph.SetTime(t);
488 ph.SetTag(idx);
489
490 // fProductionHeight, fPosX, fPosY, fCosU, fCosV (irrelevant) FIXME: Reset?
491
492 if (fSimulateWavelength)
493 {
494 const Float_t wmin = fRunHeader->GetWavelengthMin();
495 const Float_t wmax = fRunHeader->GetWavelengthMax();
496
497 ph.SetWavelength(TMath::Nint(gRandom->Uniform(wmin, wmax)));
498 }
499 }
500 }
501
502 // Re-sort the photons by time!
503 fEvt->Sort(kTRUE);
504
505 // Update maximum index
506 fStat->SetMaxIndex(npix-1);
507
508 // Shrink
509 return kTRUE;
510}
511
512// --------------------------------------------------------------------------
513//
514// Read the parameters from the resource file.
515//
516// FrequencyFixed: 0.040
517// FrequencyNSB: 5.8
518//
519// The fixed frequency is given in units fitting the units of the time.
520// Usually the time is given in nanoseconds thus, e.g., 0.040 means 40MHz.
521//
522// The FrequencyNSB is scaled by the area of the pixel in cm^2. Therefore
523// 0.040 would mean 40MHz/cm^2
524//
525Int_t MSimRandomPhotons::ReadEnv(const TEnv &env, TString prefix, Bool_t print)
526{
527 Bool_t rc = kFALSE;
528 if (IsEnvDefined(env, prefix, "FrequencyFixed", print))
529 {
530 rc = kTRUE;
531 fFreqFixed = GetEnvValue(env, prefix, "FrequencyFixed", fFreqFixed);
532 }
533
534 if (IsEnvDefined(env, prefix, "FrequencyNSB", print))
535 {
536 rc = kTRUE;
537 fFreqNSB = GetEnvValue(env, prefix, "FrequencyNSB", fFreqNSB);
538 }
539
540 if (IsEnvDefined(env, prefix, "FileNameNSB", print))
541 {
542 rc = kTRUE;
543 fFileNameNSB = GetEnvValue(env, prefix, "FileNameNSB", fFileNameNSB);
544 }
545
546 if (IsEnvDefined(env, prefix, "SimulateCherenkovSpectrum", print))
547 {
548 rc = kTRUE;
549 fSimulateWavelength = GetEnvValue(env, prefix, "SimulateCherenkovSpectrum", fSimulateWavelength);
550 }
551
552 return rc;
553}
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