source: trunk/Mars/msimcamera/MSimTrigger.cc@ 19344

Last change on this file since 19344 was 17734, checked in by tbretz, 11 years ago
Fixed the trigger pattern to be consistent with the FACT data.
File size: 26.6 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// MSimTrigger
28//
29// This task takes the pure analog channels and simulates a trigger
30// electronics.
31//
32// In a first step several channels can be summed together by a look-up table
33// fRouteAC.
34//
35// In a second step from these analog channels the output of a discriminator
36// is calculated using a threshold and optional a fixed digital signal length.
37//
38// The signal length of the digital signal emitted by the discriminator
39// can either be bound to the time the signal is above the threshold
40// defined by fDiscriminatorThreshold if fDigitalSignalLength<0 or set to a
41// fixed length (fDigitalSignalLength>0).
42//
43// With a second look-up table fCoincidenceMap the analog channels are
44// checked for coincidences. The coincidence must at least be of the length
45// defined by fCoincidenceTime. The earliest coincide is then stored as
46// trigger position.
47//
48// If a minimum multiplicity m is given, m signals above threshold
49// in the coincidence patterns are enough to emit a trigger signal.
50//
51//
52// For MAGIC1:
53// - fDigitalSignalLength between 6ns and 12ns
54// - fCoincidenceTime between 0.25ns to 1ns
55//
56//
57// Input Containers:
58// IntendedPulsePos [MParameterD]
59// MAnalogChannels
60// MRawRunHeader
61//
62// Output Containers:
63// TriggerPos [MParameterD]
64// MRawEvtHeader
65//
66//////////////////////////////////////////////////////////////////////////////
67#include "MSimTrigger.h"
68
69#include "MLog.h"
70#include "MLogManip.h"
71
72#include "MParList.h"
73#include "MParameters.h"
74
75#include "MLut.h"
76#include "MArrayI.h"
77
78#include "MRawEvtHeader.h"
79#include "MRawRunHeader.h"
80
81#include "MAnalogSignal.h"
82#include "MAnalogChannels.h"
83#include "MDigitalSignal.h"
84
85#include "MTriggerPattern.h"
86
87#include "MPedestalCam.h"
88#include "MPedestalPix.h"
89
90ClassImp(MSimTrigger);
91
92using namespace std;
93
94// --------------------------------------------------------------------------
95//
96// Default Constructor.
97//
98MSimTrigger::MSimTrigger(const char *name, const char *title)
99 : fCamera(0),
100 fPulsePos(0),
101 fTrigger(0),
102 fRunHeader(0),
103 fEvtHeader(0),
104 fElectronicNoise(0),
105 fGain(0),
106 fDiscriminatorThreshold(-1),
107 fDigitalSignalLength(8),
108 fCoincidenceTime(0.5),
109 fShiftBaseline(kTRUE),
110 fUngainSignal(kTRUE),
111 fSimulateElectronics(kTRUE),
112 fMinMultiplicity(-1),
113 fCableDelay(21),
114 fCableDamping(0.) // default Damping Set to zero, so users, who do not set
115 // the CableDamoing in the ceres.rc do not see a difference.
116
117{
118 fName = name ? name : "MSimTrigger";
119 fTitle = title ? title : "Task to simulate trigger electronics";
120}
121
122// --------------------------------------------------------------------------
123//
124// Take two TObjArrays with a collection of digital signals.
125// Every signal from one array is compared with any from the other array.
126// For all signals which overlap and which have an overlap time >gate
127// a new digital signal is created storing start time and length of overlap.
128// They are collected in a newly allocated TObjArray. A pointer to this array
129// is returned.
130//
131// The user gains owenership of the object, i.e., the user is responsible of
132// deleting the memory.
133//
134TObjArray *MSimTrigger::CalcCoincidence(const TObjArray &arr1, const TObjArray &arr2/*, Float_t gate*/) const
135{
136 TObjArray *res = new TObjArray;
137
138 if (arr1.GetEntriesFast()==0 || arr2.GetEntriesFast()==0)
139 return res;
140
141 TIter Next1(&arr1);
142 MDigitalSignal *ttl1 = 0;
143 while ((ttl1=static_cast<MDigitalSignal*>(Next1())))
144 {
145 TIter Next2(&arr2);
146 MDigitalSignal *ttl2 = 0;
147 while ((ttl2=static_cast<MDigitalSignal*>(Next2())))
148 {
149 MDigitalSignal *ttl = new MDigitalSignal(*ttl1, *ttl2);
150 /*
151 if (ttl->GetLength()<=gate)
152 {
153 delete ttl;
154 continue;
155 }
156 */
157 res->Add(ttl);
158 }
159 }
160
161 res->SetOwner();
162
163 return res;
164}
165
166class Edge : public TObject
167{
168private:
169 Double_t fEdge;
170 Int_t fRising;
171
172public:
173 Edge(Double_t t, Int_t rising) : fEdge(t), fRising(rising) { }
174 Bool_t IsSortable() const { return kTRUE; }
175 Int_t Compare(const TObject *o) const { const Edge *e = static_cast<const Edge*>(o); if (e->fEdge<fEdge) return 1; if (e->fEdge>fEdge) return -1; return 0; }
176
177 Int_t IsRising() const { return fRising; }
178 Double_t GetEdge() const { return fEdge; }
179};
180
181// --------------------------------------------------------------------------
182//
183// Calculate a multiplicity trigger on the given array(s). The idx-array
184// conatins all channels which should be checked for coincidences
185// and the ttls array conatins the arrays with the digital signals.
186//
187// For the windows in which more or euqal than threshold channels have
188// a high signal a new MDigitalSignal is created. newly allocated
189// array with a collection of these trigger signals is returned.
190//
191TObjArray *MSimTrigger::CalcMinMultiplicity(const MArrayI &idx, const TObjArray &ttls, Int_t threshold) const
192{
193 // Create a new array for the rising and falling edges of the signals
194 TObjArray times;
195 times.SetOwner();
196
197 // Fill the array with edges from all digital signals of all our channels
198 for (UInt_t k=0; k<idx.GetSize(); k++)
199 {
200 TObjArray *arr = static_cast<TObjArray*>(ttls[idx[k]]);
201
202 TIter Next(arr);
203 MDigitalSignal *ttl = 0;
204 while ((ttl=static_cast<MDigitalSignal*>(Next())))
205 {
206 times.Add(new Edge(ttl->GetStart(), 1));
207 times.Add(new Edge(ttl->GetEnd(), -1));
208 }
209 }
210
211 // Sort them in time
212 times.Sort();
213
214 // Start with no channel active
215 Int_t lvl = 0;
216
217 TObjArray *res = new TObjArray;
218 res->SetOwner();
219
220 // First remove all edges which do not change the status
221 // "below threshold" or "above threshold"
222 for (int i=0; i<times.GetEntriesFast(); i++)
223 {
224 // Get i-th edge
225 const Edge &e = *static_cast<Edge*>(times.UncheckedAt(i));
226
227 // Claculate what the number of active channels after the edge is
228 const Int_t lvl1 = lvl + e.IsRising();
229
230 // Remove edge if number of active channels before and after the
231 // edge lower is lower than the threshold or higher than
232 // the threshold
233 if (lvl+1<threshold || lvl-1>=threshold)
234 delete times.RemoveAt(i);
235
236 // keep the (now) "previous" level
237 lvl = lvl1<0 ? 0 : lvl1;
238 }
239
240 // Remove the empty slots from the array
241 times.Compress();
242
243 //
244 for (int i=0; i<times.GetEntriesFast()-1; i++)
245 {
246 // get the current edge
247 const Edge &e0 = *static_cast<Edge*>(times.UncheckedAt(i));
248
249 // go ahead if this is a falling edge
250 if (e0.IsRising()!=1)
251 continue;
252
253 // get the following edge (must be a falling edge now)
254 const Edge &e1 = *static_cast<Edge*>(times.UncheckedAt(i+1));
255
256 // calculate the length of the digital signal
257 const Double_t len = e1.GetEdge()-e0.GetEdge();
258
259 // Create a digital trigger signal
260 MDigitalSignal *ds = new MDigitalSignal(e0.GetEdge(), len);
261 //ds->SetIndex(lvl);
262 res->Add(ds);
263 }
264
265 return res;
266}
267
268// --------------------------------------------------------------------------
269//
270// Check for the necessary parameter containers. Read the luts.
271//
272Int_t MSimTrigger::PreProcess(MParList *pList)
273{
274 fTrigger = (MParameterD*)pList->FindCreateObj("MParameterD", "TriggerPos");
275 if (!fTrigger)
276 return kFALSE;
277
278 fPulsePos = (MParameterD*)pList->FindObject("IntendedPulsePos", "MParameterD");
279 if (!fPulsePos)
280 {
281 *fLog << err << "IntendedPulsePos [MParameterD] not found... aborting." << endl;
282 return kFALSE;
283 }
284
285 fCamera = (MAnalogChannels*)pList->FindObject("MAnalogChannels");
286 if (!fCamera)
287 {
288 *fLog << err << "MAnalogChannels not found... aborting." << endl;
289 return kFALSE;
290 }
291
292 fRunHeader = (MRawRunHeader*)pList->FindObject("MRawRunHeader");
293 if (!fRunHeader)
294 {
295 *fLog << err << "MRawRunHeader not found... aborting." << endl;
296 return kFALSE;
297 }
298
299 fEvtHeader = (MRawEvtHeader*)pList->FindCreateObj("MRawEvtHeader");
300 if (!fEvtHeader)
301 return kFALSE;
302
303 if (!fSimulateElectronics)
304 {
305 *fLog << inf << "Simulation of electronics switched off... first photon will trigger." << endl;
306 return kTRUE;
307 }
308
309 fElectronicNoise = 0;
310 if (fShiftBaseline)
311 {
312 fElectronicNoise = (MPedestalCam*)pList->FindObject("ElectronicNoise", "MPedestalCam");
313 if (!fElectronicNoise)
314 {
315 *fLog << err << "ElectronicNoise [MPedestalCam] not found... aborting." << endl;
316 return kFALSE;
317 }
318 *fLog << inf << "Baseline will be shifted back to 0 for discriminator." << endl;
319 }
320
321 fGain = 0;
322 if (fUngainSignal)
323 {
324 fGain = (MPedestalCam*)pList->FindObject("Gain", "MPedestalCam");
325 if (!fGain)
326 {
327 *fLog << err << "Gain [MPedestalCam] not found... aborting." << endl;
328 return kFALSE;
329 }
330 *fLog << inf << "Discriminator will be multiplied by applied gain." << endl;
331 }
332
333 fRouteAC.Delete();
334 if (!fNameRouteAC.IsNull() && fRouteAC.ReadFile(fNameRouteAC)<0)
335 return kFALSE;
336
337 fCoincidenceMap.Delete();
338 if (!fNameCoincidenceMap.IsNull() && fCoincidenceMap.ReadFile(fNameCoincidenceMap)<0)
339 return kFALSE;
340
341 // ---------------- Consistency checks ----------------------
342
343 if (!fRouteAC.IsEmpty() && !fCoincidenceMap.IsEmpty() &&
344 fCoincidenceMap.GetMaxIndex()>fRouteAC.GetNumRows()-1)
345 {
346 *fLog << err;
347 *fLog << "ERROR - AC routing produces " << fRouteAC.GetNumRows() << " analog channels," << endl;
348 *fLog << " but the coincidence map expects at least " << fCoincidenceMap.GetMaxIndex()+1 << " channels." << endl;
349 return kERROR;
350 }
351
352// if (fDiscriminatorThreshold<=0)
353// {
354// *fLog << err << "ERROR - Discriminator threshold " << fDiscriminatorThreshold << " invalid." << endl;
355// return kFALSE;
356// }
357
358 if (fElectronicNoise && !fRouteAC.IsEmpty() && !fRouteAC.IsDefaultCol())
359 {
360 // FIXME: Apply to analog channels when summing
361 *fLog << warn << "WARNING - A baseline shift doesn't make sense for sum-channels... reset." << endl;
362 fElectronicNoise = 0;
363 }
364
365 if (fGain && !fRouteAC.IsEmpty() && !fRouteAC.IsDefaultCol())
366 {
367 // FIXME: Apply to analog channels when summing
368 *fLog << warn << "WARNING - Ungain doesn't make sense for sum-channels... reset." << endl;
369 fGain = 0;
370 }
371
372
373 // ---------------- Information output ----------------------
374
375 *fLog << inf;
376
377 if (fRouteAC.IsEmpty())
378 *fLog << "Re-routing/summing of analog channels before discriminator switched off." << endl;
379 else
380 *fLog << "Using " << fNameRouteAC << " for re-routing/summing of analog channels before discriminator." << endl;
381
382 if (fCoincidenceMap.IsEmpty() && fMinMultiplicity<=0)
383 *fLog << "No coincidences of digital channels will be checked. Signal-above-threshold trigger applied." << endl;
384 else
385 {
386 *fLog << "Using ";
387 if (fCoincidenceMap.IsEmpty())
388 *fLog << "the whole camera";
389 else
390 *fLog << "patterns from " << fNameCoincidenceMap;
391 *fLog << " to check for ";
392 if (fMinMultiplicity>0)
393 *fLog << fMinMultiplicity << " multiplicity." << endl;
394 else
395 *fLog << "coincidences of the digital channels." << endl;
396 }
397
398 *fLog << "Using discriminator threshold of " << fDiscriminatorThreshold << endl;
399
400 *fLog << "Using fCableDelay " << fCableDelay << endl;
401 *fLog << "Using fCableDamping " << fCableDamping << endl;
402
403 ////////////////////////////////
404 // open some output files for debugging
405// patch_file.open("/home/fact_opr/patch_file.csv", ios_base::out);
406// clipped_file.open("/home/fact_opr/clipped_file.csv", ios_base::out);
407// digital_file.open("/home/fact_opr/digital_file.csv", ios_base::out);
408// ratescan_file.open("/home/fact_opr/ratescan_file.csv", ios_base::out);
409
410
411
412 return kTRUE;
413}
414
415/*
416class MDigitalChannel : public TObjArray
417{
418private:
419 TObjArray fArray;
420
421public:
422 MDigitalSignal *GetSignal(UInt_t i) { return static_cast<MDigitalSignal*>(fArray[i]); }
423
424};
425*/
426
427#include "MCamEvent.h"
428class MTriggerSignal : public MParContainer, public MCamEvent
429{
430private:
431 TObjArray fSignals;
432
433public:
434 MTriggerSignal() { fSignals.SetOwner(); }
435
436 void Add(MDigitalSignal *signal) { fSignals.Add(signal); }
437
438 MDigitalSignal *GetSignal(UInt_t i) { return static_cast<MDigitalSignal*>(fSignals[i]); }
439
440 void Sort() { fSignals.Sort(); }
441
442 Int_t GetNumSignals() const { return fSignals.GetEntriesFast(); }
443
444 Float_t GetFirstTrigger() const
445 {
446 MDigitalSignal *sig = static_cast<MDigitalSignal*>(fSignals[0]);
447 return sig ? sig->GetStart() : -1;
448 }
449 Int_t GetFirstIndex() const
450 {
451 MDigitalSignal *sig = static_cast<MDigitalSignal*>(fSignals[0]);
452 return sig ? sig->GetIndex() : -1;
453 }
454 Bool_t GetPixelContent(Double_t&, Int_t, const MGeomCam&, Int_t) const
455 {
456 switch (1)
457 {
458 case 1: // yes/no
459 case 2: // first time
460 case 3: // length
461 case 4: // n
462 break;
463 }
464
465 return kTRUE;
466 }
467 void DrawPixelContent(Int_t) const
468 {
469 }
470};
471
472
473void MSimTrigger::SetTrigger(Double_t pos, Int_t idx)
474{
475 // FIXME: Jitter! (Own class?)
476 fTrigger->SetVal(pos);
477 fTrigger->SetReadyToSave();
478
479 // Flag this event as triggered by the lvl1 trigger (FIXME?)
480 fEvtHeader->SetTriggerPattern(pos<0 ? 0 : 4);
481 fEvtHeader->SetNumTrigLvl1((UInt_t)idx);
482 fEvtHeader->SetReadyToSave();
483}
484
485// --------------------------------------------------------------------------
486//
487Int_t MSimTrigger::Process()
488{
489 // Invalidate trigger
490 //fTrigger->SetVal(-1);
491 // Calculate the minimum and maximum time for a valid trigger
492 const Double_t freq = fRunHeader->GetFreqSampling()/1000.;
493 const Float_t nsamp = fRunHeader->GetNumSamplesHiGain();
494 const Float_t pulspos = fPulsePos->GetVal()/freq;
495
496 // Valid range in units of bins
497 const Float_t min = fCamera->GetValidRangeMin()+pulspos;
498 const Float_t max = fCamera->GetValidRangeMax()-(nsamp-pulspos);
499
500 if (!fSimulateElectronics)
501 {
502 SetTrigger(min, -1);
503 return kTRUE;
504 }
505
506 // ================== Simulate channel bundling ====================
507
508 // FIXME: Before we can bundle the channels we have to make a copy
509 // and simulate clipping
510
511 // Check if routing should be done
512 const Bool_t empty = fRouteAC.IsEmpty();
513
514 // If no channels are summed the number of patches stays the same
515 const UInt_t npatch = empty ? fCamera->GetNumChannels() : fRouteAC.GetEntriesFast();
516
517 // Use the given analog channels as default out. If channels are
518 // summed overwrite with a newly allocated set of analog channels
519 MAnalogChannels *patches = fCamera;
520 MAnalogChannels *raw_patches = fCamera;
521 if (!empty)
522 {
523 // FIXME: Can we add gain and offset here into a new container?
524
525 patches = new MAnalogChannels(npatch, fCamera->GetNumSamples());
526 raw_patches = new MAnalogChannels(npatch, fCamera->GetNumSamples());
527 for (UInt_t patch_id=0; patch_id<npatch; patch_id++)
528 {
529 const MArrayI &row = fRouteAC.GetRow(patch_id);
530 for (UInt_t pxl_in_patch=0; pxl_in_patch<row.GetSize(); pxl_in_patch++)
531 {
532 const UInt_t pixel_id = row[pxl_in_patch];
533
534 // FIXME: Shrinking the mapping table earlier (e.g.
535 // ReInit) would avoid a lot of if's
536 if (pixel_id<fCamera->GetNumChannels())
537 {
538 (*raw_patches)[patch_id].AddSignal((*fCamera)[pixel_id]);
539 (*patches)[patch_id].AddSignal((*fCamera)[pixel_id]);
540 (*patches)[patch_id].AddSignal((*fCamera)[pixel_id], fCableDelay, fCableDamping);
541 }
542 }
543 }
544 }
545
546 // DN: 20140219 Ratescan:
547 //
548 //
549// for (UInt_t patch_id=0; patch_id<npatch; patch_id++)
550// {
551// MAnalogSignal current_patch = (*raw_patches)[patch_id];
552// float max = current_patch[0];
553// for (UInt_t i=1; i<current_patch.GetSize(); i++)
554// {
555// if (current_patch[i] > max)
556// {
557// max = current_patch[i];
558// }
559// }
560// ratescan_file << max << " ";
561// }
562// ratescan_file << endl;
563
564// // DN 20131108: DEBUGGING:
565// for (UInt_t patch_id=0; patch_id<npatch; patch_id++)
566// {
567// for (UInt_t slice=0; slice<fCamera->GetNumSamples(); slice++)
568// {
569// patch_file << (*raw_patches)[patch_id][slice] << "\t";
570// clipped_file << (*patches)[patch_id][slice] << "\t";
571// }
572// patch_file << endl;
573// clipped_file << endl;
574// }
575
576
577
578 // FIXME: Write patches
579
580 // ================== Simulate discriminators ====================
581
582 TObjArray ttls(npatch);
583 ttls.SetOwner();
584
585 for (UInt_t i=0; i<npatch; i++)
586 {
587 // FIXME: What if the gain was also allpied to the baseline?
588 const Double_t offset = fElectronicNoise ? (*fElectronicNoise)[i].GetPedestal() : 0;
589 const Double_t gain = fGain ? (*fGain)[i].GetPedestal() : 1;
590 ttls.AddAt(
591 (*patches)[i].Discriminate(
592 fDiscriminatorThreshold*gain+offset, // treshold
593 Double_t(fCableDelay), // start
594 Double_t(fCamera->GetNumSamples() - fCableDelay), // end
595 //fDigitalSignalLength // time-over-threshold, or fixed-length?
596 -1 // -1 = time-over-threshold
597 ),
598 i
599 );
600 }
601
602 // FIXME: Write TTLs!
603
604 // If analog channels had been newly allocated free memmory
605 if (patches!=fCamera)
606 delete patches;
607 if (raw_patches!=fCamera)
608 delete raw_patches;
609
610 // =================== Simulate coincidences ======================
611
612 // If the map is empty we create a one-pixel-coincidence map
613 // FIMXE: This could maybe be accelerated if the Clone can be
614 // omitted in the loop
615 if (fCoincidenceMap.IsEmpty())
616 {
617 if (fMinMultiplicity>0)
618 fCoincidenceMap.SetDefaultRow(npatch);
619 else
620 fCoincidenceMap.SetDefaultCol(npatch);
621 }
622
623 // Create an array for the individual triggers
624 MTriggerSignal triggers;
625
626 Int_t cnt = 0;
627 Int_t rmlo = 0;
628 Int_t rmhi = 0;
629
630// cout << "MSimTrigger::fMinMultiplicity = " << fMinMultiplicity << endl;
631// cout << "MSimTrigger::fCoincidenceTime = " << fCoincidenceTime << endl;
632// cout << "fCoincidenceMap.GetEntries() = " << fCoincidenceMap.GetEntries() << endl;
633// cout << "MSimTrigger::fCableDelay = " << fCableDelay << endl;
634// cout << "MSimTrigger::fCableDamping = " << fCableDamping << endl;
635// cout << "min:" << min << endl;
636// cout << "max:" << max << endl;
637
638 for (int j=0; j<fCoincidenceMap.GetEntries(); j++)
639 {
640 const MArrayI &idx = fCoincidenceMap.GetRow(j);
641
642 TObjArray *arr = 0;
643
644 if (fMinMultiplicity>0)
645 {
646 arr = CalcMinMultiplicity(idx, ttls, fMinMultiplicity);
647 }
648 else
649 {
650 arr = CalcMinMultiplicity(idx, ttls, idx.GetSize());
651 /*
652 // Start with a copy of the first coincidence channel
653 arr = static_cast<TObjArray*>(ttls[idx[0]]->Clone());
654 arr->SetOwner();
655
656 // compare to all other channels in this coincidence patch, one by one
657 for (UInt_t k=1; k<idx.GetSize() && arr->GetEntriesFast()>0; k++)
658 {
659 TObjArray *res = CalcCoincidence(*arr, *static_cast<TObjArray*>(ttls[idx[k]]));//, fCoincidenceTime);
660
661 // Delete the original array and keep the new one
662 delete arr;
663 arr = res;
664 }*/
665 }
666
667 // Count the number of totally emitted coincidence signals
668 cnt += arr->GetEntriesFast();
669
670 // Remove all signals which are not in the valid digitization range
671 // (This is not the digitization window, but the region in which
672 // the analog channels contain usefull data)
673 // and which are shorter than the defined coincidence gate.
674 TIter Next(arr);
675 MDigitalSignal *ttl = 0;
676 while ((ttl=static_cast<MDigitalSignal*>(Next())))
677 {
678 if (ttl->GetLength()<fCoincidenceTime)
679 {
680 delete arr->Remove(ttl);
681 continue;
682 }
683
684 if (ttl->GetStart()<min)
685 {
686 delete arr->Remove(ttl);
687 rmlo++;
688 continue;
689 }
690 if (ttl->GetStart()>max)
691 {
692 delete arr->Remove(ttl);
693 rmhi++;
694 continue;
695 }
696
697 // Set trigger-channel index to keep this information
698 //ttl->SetIndex(j);
699 }
700
701 // Remove the empty slots
702 arr->Compress();
703
704// cout << "ttls(j=" << j << "):";
705// TObjArray *arr2 = static_cast<TObjArray*>(ttls[j]);
706// TIter Nexty(arr);
707// MDigitalSignal *ttly = 0;
708// while ((ttly=static_cast<MDigitalSignal*>(Nexty())))
709// {
710// cout << "|"<< ttly->GetStart() << ", " << ttly->GetLength();
711// }
712// cout << endl;
713
714
715 // If we have at least one trigger keep the earliest one.
716 // FIXME: The triggers might be ordered in time automatically:
717 // To be checked!
718 // FIXME: Simulate trigger dead-time!
719 if (arr->GetEntriesFast()>0)
720 {
721 ttl = static_cast<MDigitalSignal*>(arr->RemoveAt(0));
722 // Set trigger-channel index to keep this information
723 ttl->SetIndex(j);
724 triggers.Add(ttl);
725 }
726
727 // delete the allocated space
728 delete arr;
729 }
730
731 // There are usually not enough entries that it is worth to search
732 // for the earliest instead of just sorting and taking the first one
733 // FIXME: This could be improved if checking for IsSortable
734 // is omitted
735 triggers.Sort();
736 // FIXME: Store triggers! (+ Reversed pixels?)
737
738 SetTrigger(triggers.GetFirstTrigger(), triggers.GetFirstIndex());
739
740 // No trigger issued. Go on.
741 if (triggers.GetNumSignals()==0)
742 {
743 if (rmlo>0 || rmhi>0)
744 *fLog << inf2 << GetNumExecutions() << ": " << rmlo << "/" << rmhi << " trigger out of valid range. No trigger raised." << endl;
745 return kTRUE;
746 }
747
748 // Number of patches which have triggered out of the total number of
749 // Coincidence signals emitted. (If the total number is higher than
750 // the number of triggers either some triggers had to be removed or
751 // or a patch has emitted more than one trigger signal)
752 // FIXME: inf2?
753 *fLog << inf << GetNumExecutions() << ": ";
754 *fLog << setw(3) << triggers.GetNumSignals() << " triggers left out of ";
755 *fLog << setw(3) << cnt << " (" << rmlo << "/" << rmhi << " trigger out of valid range), T=" << fTrigger->GetVal();
756 *fLog << endl;
757
758 //# Trigger characteristics: gate length (ns), min. overlapping time (ns),
759 //# amplitude and FWHM of (gaussian) single phe response for trigger:
760 //trigger_prop 3.0 0.25 1.0 2.0
761
762 return kTRUE;
763}
764
765Int_t MSimTrigger::PostProcess()
766{
767// patch_file.close();
768// clipped_file.close();
769// digital_file.close();
770// ratescan_file.close();
771 return kTRUE;
772}
773
774
775// --------------------------------------------------------------------------
776//
777// FileNameRouteac: routeac.txt
778// FileNameCoincidenceMap: coincidence.txt
779// DiscriminatorTheshold: 3.5
780// DigitalSignalLength: 8
781// CoincidenceTime: 0.5
782// SimulateElectronics: Yes
783//
784Int_t MSimTrigger::ReadEnv(const TEnv &env, TString prefix, Bool_t print)
785{
786 Bool_t rc = kFALSE;
787 if (IsEnvDefined(env, prefix, "FileNameRouteAC", print))
788 {
789 rc = kTRUE;
790 fNameRouteAC = GetEnvValue(env, prefix, "FileNameRouteAC", fNameRouteAC);
791 }
792
793 if (IsEnvDefined(env, prefix, "FileNameCoincidenceMap", print))
794 {
795 rc = kTRUE;
796 fNameCoincidenceMap = GetEnvValue(env, prefix, "FileNameCoincidenceMap", fNameCoincidenceMap);
797 }
798
799 if (IsEnvDefined(env, prefix, "DiscriminatorThreshold", print))
800 {
801 rc = kTRUE;
802 fDiscriminatorThreshold = GetEnvValue(env, prefix, "DiscriminatorThreshold", fDiscriminatorThreshold);
803 }
804
805 if (IsEnvDefined(env, prefix, "DigitalSignalLength", print))
806 {
807 rc = kTRUE;
808 fDigitalSignalLength = GetEnvValue(env, prefix, "DigitalSignalLength", fDigitalSignalLength);
809 }
810
811 if (IsEnvDefined(env, prefix, "CoincidenceTime", print))
812 {
813 rc = kTRUE;
814 fCoincidenceTime = GetEnvValue(env, prefix, "CoincidenceTime", fCoincidenceTime);
815 }
816
817 if (IsEnvDefined(env, prefix, "SimulateElectronics", print))
818 {
819 rc = kTRUE;
820 fSimulateElectronics = GetEnvValue(env, prefix, "SimulateElectronics", fSimulateElectronics);
821 }
822
823 if (IsEnvDefined(env, prefix, "MinMultiplicity", print))
824 {
825 rc = kTRUE;
826 fMinMultiplicity = GetEnvValue(env, prefix, "MinMultiplicity", fMinMultiplicity);
827 }
828
829 if (IsEnvDefined(env, prefix, "CableDelay", print))
830 {
831 rc = kTRUE;
832 fCableDelay = GetEnvValue(env, prefix, "CableDelay", fCableDelay);
833 }
834
835 if (IsEnvDefined(env, prefix, "CableDamping", print))
836 {
837 rc = kTRUE;
838 fCableDamping = GetEnvValue(env, prefix, "CableDamping", fCableDamping);
839 }
840
841
842
843 return rc;
844}
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