source: trunk/Mars/msim/MPhotonData.cc@ 19614

Last change on this file since 19614 was 19551, checked in by tbretz, 5 years ago
When the bunch size is 1 then the photons still carry their original probability (that is my interpretation) which is stored as 'bunch size'. Therefore, all bunch sizes <= 1 are ok.
File size: 16.1 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, 12/2000 <mailto:thomas.bretz@epfl.ch>
19! Author(s): Qi Zhe, 06/2007 <mailto:qizhe@astro.uni-wuerzburg.de>
20!
21! Copyright: CheObs Software Development, 2000-2010
22!
23!
24\* ======================================================================== */
25
26/////////////////////////////////////////////////////////////////////////////
27//
28// MPhotonData
29//
30// Storage container to store Corsika events
31//
32// For details on the coordinate systems see our Wiki.
33//
34// Version 1:
35// ----------
36// * First implementation
37//
38// Version 2:
39// ----------
40// - fNumPhotons
41//
42/////////////////////////////////////////////////////////////////////////////
43#include "MPhotonData.h"
44
45#include <fstream>
46#include <iostream>
47
48#include <TMath.h>
49#include <TRandom.h>
50
51#include "MLog.h"
52#include "MLogManip.h"
53
54ClassImp(MPhotonData);
55
56using namespace std;
57
58// --------------------------------------------------------------------------
59//
60// Default constructor.
61//
62MPhotonData::MPhotonData(/*const char *name, const char *title*/)
63 : fPosX(0), fPosY(0), fCosU(0), fCosV(0), fTime(0), fWavelength(0),
64 /*fNumPhotons(1),*/ fProductionHeight(0), fPrimary(MMcEvtBasic::kUNDEFINED),
65 fTag(-1), fMirrorTag(-1), fWeight(1)
66{
67 // fName = name ? name : "MPhotonData";
68 // fTitle = title ? title : "Corsika Event Data Information";
69}
70
71/*
72MPhotonData::MPhotonData(const MPhotonData &ph)
73: fPosX(ph.fPosX), fPosY(ph.fPosY), fCosU(ph.fCosU), fCosV(ph.fCosV),
74fTime(ph.fTime), fWavelength(ph.fWavelength), fNumPhotons(ph.fNumPhotons),
75fProductionHeight(ph.fProductionHeight), fPrimary(ph.fPrimary),
76fTag(ph.fTag), fWeight(ph.fWeight)
77{
78}
79*/
80
81// --------------------------------------------------------------------------
82//
83// Copy function. Copy all data members into obj.
84//
85void MPhotonData::Copy(TObject &obj) const
86{
87 MPhotonData &d = static_cast<MPhotonData&>(obj);
88
89// d.fNumPhotons = fNumPhotons;
90 d.fPosX = fPosX;
91 d.fPosY = fPosY;
92 d.fCosU = fCosU;
93 d.fCosV = fCosV;
94 d.fWavelength = fWavelength;
95 d.fPrimary = fPrimary;
96 d.fTime = fTime;
97 d.fTag = fTag;
98 d.fWeight = fWeight;
99 d.fProductionHeight = fProductionHeight;
100
101 TObject::Copy(obj);
102}
103
104// --------------------------------------------------------------------------
105//
106// Return the square cosine of the Theta-angle == 1-CosU^2-CosV^2
107//
108Double_t MPhotonData::GetCosW2() const
109{
110 return 1 - GetSinW2();
111}
112
113// --------------------------------------------------------------------------
114//
115// Return the square sine of the Theta-angle == CosU^2+CosV^2
116//
117Double_t MPhotonData::GetSinW2() const
118{
119 const Double_t sinw2 = fCosU*fCosU + fCosV*fCosV;
120 return sinw2>1 ? 1 : sinw2;
121}
122
123// --------------------------------------------------------------------------
124//
125// return the cosine of the Theta-angle == sqrt(1-CosU^2-CosV^2)
126//
127Double_t MPhotonData::GetCosW() const
128{
129 return TMath::Sqrt(GetCosW2());
130}
131
132// --------------------------------------------------------------------------
133//
134// return the sine of the Theta-angle == sqrt(CosU^2+CosV^2)
135//
136Double_t MPhotonData::GetSinW() const
137{
138 return TMath::Sqrt(GetSinW2());
139}
140
141// --------------------------------------------------------------------------
142//
143// Return the theta angle in radians
144//
145Double_t MPhotonData::GetTheta() const
146{
147 return TMath::ASin(GetSinW());
148}
149
150// --------------------------------------------------------------------------
151//
152// Return a TQuaternion with the first three components x, y, and z
153// and the fourth component the time.
154//
155TQuaternion MPhotonData::GetPosQ() const
156{
157 return TQuaternion(GetPos3(), fTime);
158}
159
160// --------------------------------------------------------------------------
161//
162// return a TQuaternion with the first three components the direction
163// moving in space (GetDir3()) and the fourth component is the
164// one devided by the speed of light (converted to cm/ns)
165//
166// FIXME: v in air!
167//
168TQuaternion MPhotonData::GetDirQ() const
169{
170 return TQuaternion(GetDir3(), 1./(TMath::C()*100/1e9));
171}
172
173// --------------------------------------------------------------------------
174//
175// Set the wavelength to a random lambda^-2 distributed value
176// between wmin and wmax.
177//
178void MPhotonData::SimWavelength(Float_t wmin, Float_t wmax)
179{
180 const Double_t w = gRandom->Uniform(wmin, wmax);
181
182 fWavelength = TMath::Nint(wmin*wmax / w);
183}
184
185
186// --------------------------------------------------------------------------
187//
188// Set the data member according to the 8 floats read from a reflector-file.
189// This function MUST reset all data-members, no matter whether these are
190// contained in the input stream.
191//
192Int_t MPhotonData::FillRfl(const Float_t f[8])
193{
194 // Check coordinate system!!!!
195 fWavelength = TMath::Nint(f[0]);
196 fPosX = f[1]; // [cm]
197 fPosY = f[2]; // [cm]
198 fCosU = f[3]; // cos to x
199 fCosV = f[4]; // cos to y
200 fTime = f[5]; // [ns]
201 fProductionHeight = f[6];
202
203 // f[7]: Camera inclination angle
204
205 fPrimary = MMcEvtBasic::kUNDEFINED;
206// fNumPhotons = 1;
207 fTag = -1;
208 fWeight = 1;
209
210 return kTRUE;
211}
212
213// --------------------------------------------------------------------------
214//
215// Set the data member according to the 7 floats read from a corsika-file.
216// This function MUST reset all data-members, no matter whether these are
217// contained in the input stream.
218//
219// Currently we exchange x and y and set y=-y to convert Corsikas coordinate
220// system intpo our own.
221//
222Int_t MPhotonData::FillCorsika(const Float_t f[7], Int_t i)
223{
224 // From the Corsika manual:
225 //
226 // f[0] : n Number of Cherenkov photons in bunch
227 // (For THIN option multiplied with thinning weight)
228 // f[1] : x [cm]
229 // f[2] : y [cm]
230 // f[3] : u direction cosine (to x axis) [u = sin(theta)cos(phi)]
231 // f[4] : v direction cosine (to y axis) [v = sin(theta)sin(phi)]
232 // f[5] : t [ns] time to first interaction or since start of atmosphere (see TSTART)
233 // f[6] : h [ch] bunch production height (except MCERFI=3)
234 // f[7] : w weight of bunch [only with THIN option]
235
236 // f[0] = MCERFI==1/2/3 && !THIN ? PHOTCM : PHOTCM*WTCER/MAX(1e-10, PROBTH)
237 // f[1] = XCER
238 // f[2] = YXCER
239 // f[3] = UEMIS
240 // f[4] = VEMIS
241 // f[5] = CARTIM
242 // f[6] = MCERFI<3 ? ZEMIS : CERDIST
243 // #if __THIN__
244 // f[7] = MCERFI==1 ? WTCER/MAX(1e-10, PROBTH) : (CEFFIC || CERWLEN ? WL*WLFLAG : WLFLAG);
245 // #endif
246 //
247 // WLFLAG = [CEFFIC=-1] [CERWLEN=1] [ELSE=0]
248 //
249 // WL = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*RDM(IRDM))
250 //
251 // WL-MIN = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*0) = WAVLGU
252 // WL-MAX = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*1) = WAVLGL
253 //
254
255 //const UInt_t n /*fWeight*/ = TMath::Nint(f[0]);
256
257 // Empty bunch (this happend at the end of events when
258 // the remaining block is filled with zeroes)
259 if (f[0]==0)
260 return kCONTINUE;
261
262 // My understanding is that each photon internally gets a weight (e.g. lambda^-2)
263 // and according to this weight a dice is thrown. The weights are still written
264 // to the output file but only for the surviving photons
265 if (f[0]>1)
266 cout << "MPhotonData::FillCorsika: WARNING - Bunch size > 1 (" << f[0] << ")" <<endl;
267
268#ifdef __MMCS__
269 // Check reuse
270 if (i >=0)
271 {
272 const Int_t reuse = (n/1000)%100; // Force this to be 1!
273 if (reuse!=i)
274 {
275 cout << "REUSE " << reuse << " " << i << " " << n << endl;
276 return kCONTINUE;
277 }
278 }
279
280 // This seems to be special to mmcs
281 fWavelength = n%1000;
282 fPrimary = MMcEvtBasic::ParticleId_t(n/100000);
283#else
284 fWavelength = 0;
285 fPrimary = MMcEvtBasic::kUNDEFINED;
286#endif
287
288 // x=north, y=west
289 //fPosX = f[1]; // [cm]
290 //fPosY = f[2]; // [cm]
291 //fCosU = f[3]; // cos to x
292 //fCosV = f[4]; // cos to y
293 // x=west, y=south
294 fPosX = f[2]; // [cm]
295 fPosY = -f[1]; // [cm]
296
297 fCosU = f[4]; // cos to x
298 fCosV = -f[3]; // cos to y
299
300 fTime = f[5]; // [ns]
301
302 fProductionHeight = f[6]; // [cm]
303
304 // Now reset all data members which are not in the stream
305 fTag = -1;
306 fWeight = 1;
307
308 return kTRUE;
309}
310
311Int_t MPhotonData::FillCorsikaThin(const Float_t f[8], Int_t i)
312{
313 // DATAB2(LHCER(IBUF)+1,IBUF) = PHOTCM*WTCER/MAX(1.D-10,PROBTH)
314
315 // For the THIN option the photon bunch size is multiplied with the
316 // thinning weight. See Sect. 4.89 page 99.
317
318 /*
319 #if __THIN__
320 C (CONTAINING UP TO 39 BUNCHES, 8 WORDS EACH)
321 C
322 C 8*(N-1)+1 NUMBER OF PHOTONS IN BUNCH
323 C (FOR STANDARD PARTICLE OUTPUT FILE:
324 C 99.E5 + NINT(NUMBER OF PHOTONS IN BUNCH)*10 + 1
325 C 8*(N-1)+2 X- COORDINATE IN CM
326 C 8*(N-1)+3 Y- COORDINATE IN CM
327 C 8*(N-1)+4 DIRECTION COSINUS TO X AXIS
328 C 8*(N-1)+5 DIRECTION COSINUS TO Y AXIS
329 C 8*(N-1)+6 T TIME SINCE FIRST INTERACTION (OR ENTRANCE INTO
330 C ATMOSPHERE) IN NSEC
331 C 8*(N-1)+7 PRODUCTION HEIGHT OF BUNCH IN CM
332 C 8*(N-1)+8 WEIGHT OF BUNCH
333 #else
334 */
335
336 // From the Corsika manual:
337 //
338 // f[0] : n Number of Cherenkov photons in bunch
339 // (For THIN option multiplied with thinning weight)
340 // f[1] : x [cm]
341 // f[2] : y [cm]
342 // f[3] : u direction cosine (to x axis) [u = sin(theta)cos(phi)]
343 // f[4] : v direction cosine (to y axis) [v = sin(theta)sin(phi)]
344 // f[5] : t [ns] time to first interaction or since start of atmosphere (see TSTART)
345 // f[6] : h [ch] bunch production height (except MCERFI=3)
346 // f[7] : w weight of bunch [only with THIN option]
347
348 // f[0] = MCERFI==1/2/3 && !THIN ? PHOTCM : PHOTCM*WTCER/MAX(1e-10, PROBTH)
349 // f[1] = XCER
350 // f[2] = YXCER
351 // f[3] = UEMIS
352 // f[4] = VEMIS
353 // f[5] = CARTIM
354 // f[6] = MCERFI<3 ? ZEMIS : CERDIST
355 // #if __THIN__
356 // f[7] = MCERFI==1 ? WTCER/MAX(1e-10, PROBTH) : (CEFFIC || CERWLEN ? WL*WLFLAG : WLFLAG);
357 // #endif
358 //
359 // WLFLAG = [CEFFIC=-1] [CERWLEN=1] [ELSE=0]
360 //
361 // WL = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*RDM(IRDM))
362 //
363 // WL-MIN = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*0) = WAVLGU
364 // WL-MAX = 1./(1./WAVLGU+(1./WAVLGL-1./WAVLGU)*1) = WAVLGL
365 //
366
367 //const UInt_t n /*fWeight*/ = TMath::Nint(f[0]);
368
369 // Empty bunch (this happend at the end of events when
370 // the remaining block is filled with zeroes)
371 if (f[0]==0)
372 return kCONTINUE;
373
374 // My understanding is that each photon internally gets a weight (e.g. lambda^-2)
375 // and according to this weight a dice is thrown. The weights are still written
376 // to the output file but only for the surviving photons
377 if (f[0]>1)
378 cout << "MPhotonData::FillCorsikaThin: WARNING - Bunch size > 1 (" << f[0] << ")" <<endl;
379
380 // x=north, y=west
381 //fPosX = f[1]; // [cm]
382 //fPosY = f[2]; // [cm]
383 //fCosU = f[3]; // cos to x
384 //fCosV = f[4]; // cos to y
385 // x=west, y=south
386 fPosX = f[2]; // [cm]
387 fPosY = -f[1]; // [cm]
388
389 fCosU = f[4]; // cos to x
390 fCosV = -f[3]; // cos to y
391
392 fTime = f[5]; // [ns]
393
394 fProductionHeight = f[6]; // [cm]
395 // f[7]<0: Photoelectron bunches of specific wavelength (if __CEFFIC__)
396 // f[7]>0: __CERWLEN__ (but __CEFFIC takes priority)
397
398 fWavelength = TMath::Abs(f[7]);
399
400 // Now reset all data members which are not in the stream
401 fPrimary = MMcEvtBasic::kUNDEFINED;
402 fTag = -1;
403 fWeight = 1;
404
405 return kTRUE;
406}
407
408// --------------------------------------------------------------------------
409//
410// Set the data member according to the 8 shorts read from a eventio-file.
411// This function MUST reset all data-members, no matter whether these are
412// contained in the input stream.
413//
414// Currently we exchange x and y and set y=-y to convert Corsikas coordinate
415// system into our own.
416//
417Int_t MPhotonData::FillEventIO(const Short_t f[8])
418{
419 // From 5.5 compact_bunch:
420 // https://www.mpi-hd.mpg.de/hfm/~bernlohr/iact-atmo/iact_refman.pdf
421
422 // photons in this bunch f[6]/100.
423
424 fPosY = -f[0]/10.; // ypos relative to telescope [cm]
425 fPosX = f[1]/10.; // xpos relative to telescope [cm]
426 fCosV = -f[2]/30000.; // cos to y
427 fCosU = f[3]/30000.; // cos to x
428
429 fTime = f[4]/10.; // a relative arival time [ns]
430 fProductionHeight = pow(10, f[5]/1000.); // altitude of emission a.s.l. [cm]
431 fWavelength = TMath::Abs(f[7]); // wavelength [nm]: 0 undetermined, <0 already in p.e.
432
433 // Now reset all data members which are not in the stream
434 fPrimary = MMcEvtBasic::kUNDEFINED;
435 fTag = -1;
436 fWeight = 1;
437
438 return 1;
439}
440
441// --------------------------------------------------------------------------
442//
443// Set the data member according to the 8 floats read from a eventio-file.
444// This function MUST reset all data-members, no matter whether these are
445// contained in the input stream.
446//
447// Currently we exchange x and y and set y=-y to convert Corsikas coordinate
448// system into our own.
449//
450Int_t MPhotonData::FillEventIO(const Float_t f[8])
451{
452 // photons in this bunch
453 const UInt_t n = TMath::Nint(f[6]);
454 if (n==0)
455 return 0;
456
457 fPosX = f[1]; // xpos relative to telescope [cm]
458 fPosY = -f[0]; // ypos relative to telescope [cm]
459 fCosU = f[3]; // cos to x
460 fCosV = -f[2]; // cos to y
461 //fTime = f[4]; // a relative arival time [ns]
462 //fProductionHeight = f[5]; // altitude of emission [cm]
463 fWavelength = 0; // so far always zeor = unspec. [nm]
464
465 // Now reset all data members which are not in the stream
466 fPrimary = MMcEvtBasic::kUNDEFINED;
467 fTag = -1;
468 fWeight = 1;
469
470 return n-1;
471}
472
473/*
474// --------------------------------------------------------------------------
475//
476// Read seven floats from the stream and call FillCorsika for them.
477//
478Int_t MPhotonData::ReadCorsikaEvt(istream &fin)
479{
480 Float_t f[7];
481 fin.read((char*)&f, 7*4);
482
483 const Int_t rc = FillCorsika(f);
484
485 return rc==kTRUE ? !fin.eof() : rc;
486}
487
488// --------------------------------------------------------------------------
489//
490// Read eight floats from the stream and call FillRfl for them.
491//
492Int_t MPhotonData::ReadRflEvt(istream &fin)
493{
494 Float_t f[8];
495 fin.read((char*)&f, 8*4);
496
497 const Int_t rc = FillRfl(f);
498
499 return rc==kTRUE ? !fin.eof() : rc;
500}
501*/
502
503// --------------------------------------------------------------------------
504//
505// Print contents. The tag and Weight are only printed if they are different
506// from the default.
507//
508void MPhotonData::Print(Option_t *) const
509{
510 gLog << inf << endl;
511 // gLog << "Num Photons: " << fNumPhotons << " from " << MMcEvtBasic::GetParticleName(fPrimary) << endl;
512 if (fPrimary!=MMcEvtBasic::kUNDEFINED)
513 gLog << "Origin: " << MMcEvtBasic::GetParticleName(fPrimary) << endl;
514 gLog << "Wavelength: " << fWavelength << "nm" << endl;
515 gLog << "Pos X/Y Cos U/V: " << fPosX << "/" << fPosY << " " << fCosU << "/" << fCosV << endl;
516 gLog << "Time/Prod.Height: " << fTime << "ns/" << fProductionHeight/100 << "m" << endl;
517 if (fTag>=0)
518 gLog << "Tag: " << fTag << endl;
519 if (fWeight!=1)
520 gLog << "Weight: " << fWeight << endl;
521}
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