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ETLElectronicsSim.cc
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2 
4 #include "CLHEP/Random/RandGaussQ.h"
5 
6 using namespace mtd;
7 
9  debug_( pset.getUntrackedParameter<bool>("debug",false) ),
10  bxTime_(pset.getParameter<double>("bxTime") ),
11  sigmaEta_( pset.getParameter<std::string>("etaResolution") ),
12  adcNbits_( pset.getParameter<uint32_t>("adcNbits") ),
13  tdcNbits_( pset.getParameter<uint32_t>("tdcNbits") ),
14  adcSaturation_MIP_( pset.getParameter<double>("adcSaturation_MIP") ),
15  adcLSB_MIP_( adcSaturation_MIP_/std::pow(2.,adcNbits_) ),
16  adcThreshold_MIP_( pset.getParameter<double>("adcThreshold_MIP") ),
17  toaLSB_ns_( pset.getParameter<double>("toaLSB_ns") ) {
18 }
19 
20 
23  CLHEP::HepRandomEngine *hre) const {
24 
25  MTDSimHitData chargeColl, toa;
26 
27 
28  std::vector<double> emptyV;
29  std::vector<double> eta(1);
30 
31  for(MTDSimHitDataAccumulator::const_iterator it=input.begin();
32  it!=input.end();
33  it++) {
34 
35  chargeColl.fill(0.f);
36  toa.fill(0.f);
37  for(size_t i=0; i<it->second.hit_info[0].size(); i++) {
38 
39  if ( (it->second).hit_info[0][i] < adcThreshold_MIP_ ) continue;
40 
41  // time of arrival
42  float finalToA = (it->second).hit_info[1][i];
43 
44  // Gaussian smearing of the time of arrival
45  eta[0] = 2.; // This is just temporary. Once the RECO geometry is
46  // available, the actual module eta will be used.
47  double sigmaToA = sigmaEta_.evaluate(eta, emptyV);
48 
49  if ( sigmaToA > 0. )
50  finalToA += CLHEP::RandGaussQ::shoot(hre, 0., sigmaToA);
51 
52  // fill the time and charge arrays
53  const unsigned int ibucket = std::floor( finalToA/bxTime_ );
54  if ( (i+ibucket) >= chargeColl.size() ) continue;
55 
56  chargeColl[i+ibucket] += (it->second).hit_info[0][i];
57 
58  if ( toa[i+ibucket] == 0. || (finalToA-ibucket*bxTime_) < toa[i+ibucket] )
59  toa[i+ibucket] = finalToA - ibucket*bxTime_;
60 
61  }
62 
63  // run the shaper to create a new data frame
64  ETLDataFrame rawDataFrame( it->first.detid_ );
65  runTrivialShaper(rawDataFrame,chargeColl,toa, it->first.row_, it->first.column_);
66  updateOutput(output,rawDataFrame);
67 
68  }
69 
70 }
71 
72 
74  const mtd::MTDSimHitData& chargeColl,
75  const mtd::MTDSimHitData& toa,
76  const uint8_t row, const uint8_t col) const {
77  bool debug = debug_;
78 #ifdef EDM_ML_DEBUG
79  for(int it=0; it<(int)(chargeColl.size()); it++) debug |= (chargeColl[it]>adcThreshold_fC_);
80 #endif
81 
82  if(debug) edm::LogVerbatim("ETLElectronicsSim") << "[runTrivialShaper]" << std::endl;
83 
84  //set new ADCs
85  for(int it=0; it<(int)(chargeColl.size()); it++)
86  {
87  //brute force saturation, maybe could to better with an exponential like saturation
88  const uint32_t adc=std::floor( std::min(chargeColl[it],adcSaturation_MIP_) / adcLSB_MIP_ );
89  const uint32_t tdc_time=std::floor( toa[it] / toaLSB_ns_ );
90  ETLSample newSample;
91  newSample.set(chargeColl[it] > adcThreshold_MIP_,false,tdc_time,adc,row,col);
92  dataFrame.setSample(it,newSample);
93 
94  if(debug) edm::LogVerbatim("ETLElectronicsSim") << adc << " (" << chargeColl[it] << "/" << adcLSB_MIP_ << ") ";
95  }
96 
97  if(debug) {
98  std::ostringstream msg;
99  dataFrame.print(msg);
100  edm::LogVerbatim("ETLElectronicsSim") << msg.str() << std::endl;
101  }
102 }
103 
105  const ETLDataFrame& rawDataFrame) const {
106  int itIdx(9);
107  if(rawDataFrame.size()<=itIdx+2) return;
108 
109  ETLDataFrame dataFrame( rawDataFrame.id() );
110  dataFrame.resize(dfSIZE);
111  bool putInEvent(false);
112  for(int it=0;it<dfSIZE; ++it) {
113  dataFrame.setSample(it, rawDataFrame[itIdx-2+it]);
114  if(it==2) putInEvent = rawDataFrame[itIdx-2+it].threshold();
115  }
116 
117  if(putInEvent) {
118  coll.push_back(dataFrame);
119  }
120 }
void runTrivialShaper(ETLDataFrame &dataFrame, const mtd::MTDSimHitData &chargeColl, const mtd::MTDSimHitData &toa, const uint8_t row, const uint8_t column) const
void push_back(T const &t)
ETLElectronicsSim(const edm::ParameterSet &pset)
std::unordered_map< MTDCellId, MTDCellInfo > MTDSimHitDataAccumulator
const float toaLSB_ns_
int size() const
total number of samples in the digi
Definition: FTLDataFrameT.h:47
std::array< MTDSimData_t, nSamples > MTDSimHitData
wrapper for a data word
Definition: ETLSample.h:13
static std::string const input
Definition: EdmProvDump.cc:48
const reco::FormulaEvaluator sigmaEta_
void updateOutput(ETLDigiCollection &coll, const ETLDataFrame &rawDataFrame) const
void resize(size_t s)
allow to set size
Definition: FTLDataFrameT.h:52
double evaluate(V const &iVariables, P const &iParameters) const
double f[11][100]
void setSample(int i, const S &sample)
Definition: FTLDataFrameT.h:59
T min(T a, T b)
Definition: MathUtil.h:58
constexpr int adc(sample_type sample)
get the ADC sample (12 bits)
#define debug
Definition: HDRShower.cc:19
JetCorrectorParametersCollection coll
Definition: classes.h:10
void run(const mtd::MTDSimHitDataAccumulator &input, ETLDigiCollection &output, CLHEP::HepRandomEngine *hre) const
tuple msg
Definition: mps_check.py:279
const float adcLSB_MIP_
void set(bool thr, bool mode, uint16_t toa, uint16_t data, uint8_t row, uint8_t col)
Definition: ETLSample.h:38
col
Definition: cuy.py:1010
Readout digi for HGC.
Definition: FTLDataFrameT.h:14
const float adcSaturation_MIP_
void print(std::ostream &out=std::cout)
Definition: FTLDataFrameT.h:60
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
const D & id() const
det id
Definition: FTLDataFrameT.h:32
const float adcThreshold_MIP_