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HGCHEbackDigitizer.cc
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2 
3 #include "CLHEP/Random/RandPoissonQ.h"
4 #include "CLHEP/Random/RandGaussQ.h"
5 
8 
9 #include "vdt/vdtMath.h"
10 
11 using namespace hgc_digi;
12 using namespace hgc_digi_utils;
13 
14 //
17  algo_ = cfg.getParameter<uint32_t>("algo");
18  scaleByTileArea_ = cfg.getParameter<bool>("scaleByTileArea");
19  scaleBySipmArea_ = cfg.getParameter<bool>("scaleBySipmArea");
20  sipmMapFile_ = cfg.getParameter<std::string>("sipmMap");
21  scaleByDose_ = cfg.getParameter<edm::ParameterSet>("noise").getParameter<bool>("scaleByDose");
22  unsigned int scaleByDoseAlgo = cfg.getParameter<edm::ParameterSet>("noise").getParameter<uint32_t>("scaleByDoseAlgo");
23  doseMapFile_ = cfg.getParameter<edm::ParameterSet>("noise").getParameter<std::string>("doseMap");
24  noise_MIP_ = cfg.getParameter<edm::ParameterSet>("noise").getParameter<double>("noise_MIP");
25  thresholdFollowsMIP_ = cfg.getParameter<bool>("thresholdFollowsMIP");
26  keV2MIP_ = cfg.getParameter<double>("keV2MIP");
27  this->keV2fC_ = 1.0; //keV2MIP_; // hack for HEB
28  nPEperMIP_ = cfg.getParameter<double>("nPEperMIP");
29  nTotalPE_ = cfg.getParameter<double>("nTotalPE");
30  xTalk_ = cfg.getParameter<double>("xTalk");
31  sdPixels_ = cfg.getParameter<double>("sdPixels");
32 
35 }
36 
37 //
38 void HGCHEbackDigitizer::runDigitizer(std::unique_ptr<HGCalDigiCollection>& digiColl,
39  HGCSimHitDataAccumulator& simData,
40  const CaloSubdetectorGeometry* theGeom,
41  const std::unordered_set<DetId>& validIds,
42  uint32_t digitizationType,
43  CLHEP::HepRandomEngine* engine) {
44  if (algo_ == 0)
45  runEmptyDigitizer(digiColl, simData, theGeom, validIds, engine);
46  else if (algo_ == 1)
47  runCaliceLikeDigitizer(digiColl, simData, theGeom, validIds, engine);
48  else if (algo_ == 2)
49  runRealisticDigitizer(digiColl, simData, theGeom, validIds, engine);
50 }
51 
52 void HGCHEbackDigitizer::runEmptyDigitizer(std::unique_ptr<HGCalDigiCollection>& digiColl,
53  HGCSimHitDataAccumulator& simData,
54  const CaloSubdetectorGeometry* theGeom,
55  const std::unordered_set<DetId>& validIds,
56  CLHEP::HepRandomEngine* engine) {
57  HGCSimHitData chargeColl, toa;
58  // this represents a cell with no signal charge
59  HGCCellInfo zeroData;
60  zeroData.hit_info[0].fill(0.f); //accumulated energy
61  zeroData.hit_info[1].fill(0.f); //time-of-flight
62 
63  for (const auto& id : validIds) {
64  chargeColl.fill(0.f);
65  toa.fill(0.f);
66  HGCSimHitDataAccumulator::iterator it = simData.find(id);
67  HGCCellInfo& cell = (simData.end() == it ? zeroData : it->second);
68  addCellMetadata(cell, theGeom, id);
69 
70  for (size_t i = 0; i < cell.hit_info[0].size(); ++i) {
71  //convert total energy keV->MIP, since converted to keV in accumulator
72  const float totalIniMIPs(cell.hit_info[0][i] * keV2MIP_);
73 
74  //store
75  chargeColl[i] = totalIniMIPs;
76  }
77 
78  //init a new data frame and run shaper
79  HGCalDataFrame newDataFrame(id);
80  this->myFEelectronics_->runShaper(newDataFrame, chargeColl, toa, engine);
81 
82  //prepare the output
83  this->updateOutput(digiColl, newDataFrame);
84  }
85 }
86 
87 void HGCHEbackDigitizer::runRealisticDigitizer(std::unique_ptr<HGCalDigiCollection>& digiColl,
88  HGCSimHitDataAccumulator& simData,
89  const CaloSubdetectorGeometry* theGeom,
90  const std::unordered_set<DetId>& validIds,
91  CLHEP::HepRandomEngine* engine) {
92  //switch to true if you want to print some details
93  constexpr bool debug(false);
94 
95  HGCSimHitData chargeColl, toa;
96  // this represents a cell with no signal charge
97  HGCCellInfo zeroData;
98  zeroData.hit_info[0].fill(0.f); //accumulated energy
99  zeroData.hit_info[1].fill(0.f); //time-of-flight
100 
101  // needed to compute the radiation and geometry scale factors
102  scal_.setGeometry(theGeom);
103 
104  for (const auto& id : validIds) {
105  chargeColl.fill(0.f);
106  toa.fill(0.f);
107  HGCSimHitDataAccumulator::iterator it = simData.find(id);
108  HGCCellInfo& cell = (simData.end() == it ? zeroData : it->second);
109  addCellMetadata(cell, theGeom, id);
110 
111  float scaledPePerMip = nPEperMIP_; //needed to scale according to tile geometry
112  float tunedNoise = nPEperMIP_ * noise_MIP_; //flat noise case
113  float sipmFactor = 1.; //standard 2 mm^2 sipm
114 
115  if (id.det() == DetId::HGCalHSc) //skip those geometries that have HE used as BH
116  {
119  radius = scal_.computeRadius(id);
120 
121  //take into account the tile size
122  if (scaleByTileArea_)
123  scaledPePerMip *= scal_.scaleByTileArea(id, radius);
124 
125  //take into account the darkening of the scintillator and SiPM dark current
126  if (scaleByDose_) {
127  auto dosePair = scal_.scaleByDose(id, radius);
128  scaledPePerMip *= dosePair.first;
129  tunedNoise = dosePair.second;
130  }
131 
132  //take into account the sipm size
133  if (scaleBySipmArea_) {
134  sipmFactor = scal_.scaleBySipmArea(id, radius[0]);
135  scaledPePerMip *= sipmFactor;
136  tunedNoise *= sqrt(sipmFactor);
137  }
138  }
139 
140  //set mean for poissonian noise
141  float meanN = std::pow(tunedNoise, 2);
142 
143  for (size_t i = 0; i < cell.hit_info[0].size(); ++i) {
144  //convert total energy keV->MIP, since converted to keV in accumulator
145  float totalIniMIPs(cell.hit_info[0][i] * keV2MIP_);
146 
147  //generate the number of photo-electrons from the energy deposit
148  const uint32_t npeS = std::floor(CLHEP::RandPoissonQ::shoot(engine, totalIniMIPs * scaledPePerMip) + 0.5);
149 
150  //generate the noise associated to the dark current
151  const uint32_t npeN = std::floor(CLHEP::RandPoissonQ::shoot(engine, meanN) + 0.5);
152 
153  //total number of pe from signal + noise (not subtracting pedestal)
154  const uint32_t npe = npeS + npeN;
155 
156  //take into account SiPM saturation
157  float nTotalPixels = nTotalPE_ * sipmFactor;
158  const float x = vdt::fast_expf(-((float)npe) / nTotalPixels);
159  uint32_t nPixel(0);
160  if (xTalk_ * x != 1)
161  nPixel = (uint32_t)std::max(nTotalPixels * (1.f - x) / (1.f - xTalk_ * x), 0.f);
162 
163  //take into account the gain fluctuations of each pixel
164  //const float nPixelTot = nPixel + sqrt(nPixel) * CLHEP::RandGaussQ::shoot(engine, 0., 0.05); //FDG: just a note for now, par to be defined
165 
166  //scale to calibrated response depending on the thresholdFollowsMIP_ flag
167  float totalMIPs = thresholdFollowsMIP_ ? std::max((npe - meanN), 0.f) / nPEperMIP_ : nPixel / nPEperMIP_;
168 
169  if (debug && totalIniMIPs > 0) {
170  LogDebug("HGCHEbackDigitizer") << "npeS: " << npeS << " npeN: " << npeN << " npe: " << npe
171  << " meanN: " << meanN << " noise_MIP_: " << noise_MIP_
172  << " nPEperMIP_: " << nPEperMIP_ << " scaledPePerMip: " << scaledPePerMip
173  << " nPixel: " << nPixel;
174  LogDebug("HGCHEbackDigitizer") << "totalIniMIPs: " << totalIniMIPs << " totalMIPs: " << totalMIPs << std::endl;
175  }
176 
177  //store charge
178  chargeColl[i] = totalMIPs;
179 
180  //update time of arrival
181  toa[i] = cell.hit_info[1][i];
182  if (myFEelectronics_->toaMode() == HGCFEElectronics<HGCalDataFrame>::WEIGHTEDBYE && totalIniMIPs > 0)
183  toa[i] = cell.hit_info[1][i] / totalIniMIPs;
184  }
185 
186  //init a new data frame and run shaper
187  HGCalDataFrame newDataFrame(id);
188  float adcThr = this->myFEelectronics_->getADCThreshold(); //this is in MIPs
189  float adcLsb = this->myFEelectronics_->getADClsb();
190  uint32_t thrADC(thresholdFollowsMIP_ ? std::floor(adcThr / adcLsb * scaledPePerMip / nPEperMIP_)
191  : std::floor(adcThr / adcLsb));
192 
193  this->myFEelectronics_->runShaper(newDataFrame, chargeColl, toa, engine, thrADC);
194 
195  //prepare the output
196  this->updateOutput(digiColl, newDataFrame);
197  }
198 }
199 
200 //
201 void HGCHEbackDigitizer::runCaliceLikeDigitizer(std::unique_ptr<HGCalDigiCollection>& digiColl,
202  HGCSimHitDataAccumulator& simData,
203  const CaloSubdetectorGeometry* theGeom,
204  const std::unordered_set<DetId>& validIds,
205  CLHEP::HepRandomEngine* engine) {
206  //switch to true if you want to print some details
207  constexpr bool debug(false);
208 
209  HGCSimHitData chargeColl, toa;
210 
211  // this represents a cell with no signal charge
212  HGCCellInfo zeroData;
213  zeroData.hit_info[0].fill(0.f); //accumulated energy
214  zeroData.hit_info[1].fill(0.f); //time-of-flight
215 
216  for (const auto& id : validIds) {
217  chargeColl.fill(0.f);
218  HGCSimHitDataAccumulator::iterator it = simData.find(id);
219  HGCCellInfo& cell = (simData.end() == it ? zeroData : it->second);
220  addCellMetadata(cell, theGeom, id);
221 
222  for (size_t i = 0; i < cell.hit_info[0].size(); ++i) {
223  //convert total energy keV->MIP, since converted to keV in accumulator
224  const float totalIniMIPs(cell.hit_info[0][i] * keV2MIP_);
225 
226  //generate random number of photon electrons
227  const uint32_t npe = std::floor(CLHEP::RandPoissonQ::shoot(engine, totalIniMIPs * nPEperMIP_));
228 
229  //number of pixels
230  const float x = vdt::fast_expf(-((float)npe) / nTotalPE_);
231  uint32_t nPixel(0);
232  if (xTalk_ * x != 1)
233  nPixel = (uint32_t)std::max(nTotalPE_ * (1.f - x) / (1.f - xTalk_ * x), 0.f);
234 
235  //update signal
236  if (sdPixels_ != 0)
237  nPixel = (uint32_t)std::max(CLHEP::RandGaussQ::shoot(engine, (double)nPixel, sdPixels_), 0.);
238 
239  //convert to MIP again and saturate
240  float totalMIPs(0.f), xtalk = 0.f;
241  const float peDiff = nTotalPE_ - (float)nPixel;
242  if (peDiff != 0.f) {
243  xtalk = (nTotalPE_ - xTalk_ * ((float)nPixel)) / peDiff;
244  if (xtalk > 0.f && nPEperMIP_ != 0.f)
245  totalMIPs = (nTotalPE_ / nPEperMIP_) * vdt::fast_logf(xtalk);
246  }
247 
248  //add noise (in MIPs)
249  chargeColl[i] = totalMIPs;
250  if (noise_MIP_ != 0)
251  chargeColl[i] += std::max(CLHEP::RandGaussQ::shoot(engine, 0., noise_MIP_), 0.);
252  if (debug && cell.hit_info[0][i] > 0)
253  edm::LogVerbatim("HGCDigitizer") << "[runCaliceLikeDigitizer] xtalk=" << xtalk << " En=" << cell.hit_info[0][i]
254  << " keV -> " << totalIniMIPs << " raw-MIPs -> " << chargeColl[i]
255  << " digi-MIPs";
256  }
257 
258  //init a new data frame and run shaper
259  HGCalDataFrame newDataFrame(id);
260  this->myFEelectronics_->runShaper(newDataFrame, chargeColl, toa, engine);
261 
262  //prepare the output
263  this->updateOutput(digiColl, newDataFrame);
264  }
265 }
266 
267 //
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Definition: HGCHEbackDigitizer.h:26
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