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CastorFastTowerProducer Class Reference

#include <FastSimulation/ForwardDetectors/plugins/CastorFastTowerProducer.cc>

Inheritance diagram for CastorFastTowerProducer:
edm::stream::EDProducer<>

Public Member Functions

 CastorFastTowerProducer (const edm::ParameterSet &)
 
 ~CastorFastTowerProducer () override
 
- Public Member Functions inherited from edm::stream::EDProducer<>
 EDProducer ()=default
 
bool hasAbilityToProduceInBeginLumis () const final
 
bool hasAbilityToProduceInBeginProcessBlocks () const final
 
bool hasAbilityToProduceInBeginRuns () const final
 
bool hasAbilityToProduceInEndLumis () const final
 
bool hasAbilityToProduceInEndProcessBlocks () const final
 
bool hasAbilityToProduceInEndRuns () const final
 

Private Types

typedef std::vector< reco::CastorTowerCastorTowerCollection
 
typedef math::XYZPointD Point
 
typedef ROOT::Math::RhoEtaPhiPoint TowerPoint
 

Private Member Functions

double make_noise ()
 
void produce (edm::Event &, const edm::EventSetup &) override
 

Additional Inherited Members

- Public Types inherited from edm::stream::EDProducer<>
typedef CacheContexts< T... > CacheTypes
 
typedef CacheTypes::GlobalCache GlobalCache
 
typedef AbilityChecker< T... > HasAbility
 
typedef CacheTypes::LuminosityBlockCache LuminosityBlockCache
 
typedef LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCacheLuminosityBlockContext
 
typedef CacheTypes::LuminosityBlockSummaryCache LuminosityBlockSummaryCache
 
typedef CacheTypes::RunCache RunCache
 
typedef RunContextT< RunCache, GlobalCacheRunContext
 
typedef CacheTypes::RunSummaryCache RunSummaryCache
 

Detailed Description

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>="">

Definition at line 17 of file CastorFastTowerProducer.h.

Member Typedef Documentation

◆ CastorTowerCollection

Definition at line 29 of file CastorFastTowerProducer.h.

◆ Point

Definition at line 27 of file CastorFastTowerProducer.h.

◆ TowerPoint

typedef ROOT::Math::RhoEtaPhiPoint CastorFastTowerProducer::TowerPoint
private

Definition at line 28 of file CastorFastTowerProducer.h.

Constructor & Destructor Documentation

◆ CastorFastTowerProducer()

CastorFastTowerProducer::CastorFastTowerProducer ( const edm::ParameterSet iConfig)
explicit

Definition at line 54 of file CastorFastTowerProducer.cc.

54  {
55  //register your products
56  produces<CastorTowerCollection>();
57 
58  //now do what ever other initialization is needed
59 }

◆ ~CastorFastTowerProducer()

CastorFastTowerProducer::~CastorFastTowerProducer ( )
override

Definition at line 61 of file CastorFastTowerProducer.cc.

61  {
62  // do anything here that needs to be done at desctruction time
63  // (e.g. close files, deallocate resources etc.)
64 }

Member Function Documentation

◆ make_noise()

double CastorFastTowerProducer::make_noise ( )
private

Definition at line 356 of file CastorFastTowerProducer.cc.

356  {
357  double result = -1.;
358  TRandom3 r2(0);
359  double mu_noise = 0.053; // GeV (from 1.214 ADC) per channel
360  double sigma_noise = 0.027; // GeV (from 0.6168 ADC) per channel
361 
362  while (result < 0.) {
363  result = r2.Gaus(mu_noise, sigma_noise);
364  }
365 
366  return result;
367 }

References diffTwoXMLs::r2, and mps_fire::result.

Referenced by produce().

◆ produce()

void CastorFastTowerProducer::produce ( edm::Event iEvent,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 71 of file CastorFastTowerProducer.cc.

71  {
72  using namespace edm;
73  using namespace reco;
74  using namespace std;
75  using namespace TMath;
76 
77  //
78  // Make CastorTower objects
79  //
80 
81  //cout << "entering event" << endl;
82 
84  iEvent.getByLabel("genParticles", genParticles);
85 
86  // make pointer to towers that will be made
87  unique_ptr<CastorTowerCollection> CastorTowers(new CastorTowerCollection);
88 
89  // declare castor array
90  double castorplus[4][16]; // (0,x): Energies - (1,x): emEnergies - (2,x): hadEnergies - (3,x): phi position - eta = 5.9
91  double castormin[4][16]; // (0,x): Energies - (1,x): emEnergies - (2,x): hadEnergies - (3,x): phi position - eta = -5.9
92  // set phi values of array sectors and everything else to zero
93  for (int j = 0; j < 16; j++) {
94  castorplus[3][j] = -2.94524 + j * 0.3927;
95  castormin[3][j] = -2.94524 + j * 0.3927;
96  castorplus[0][j] = 0.;
97  castormin[0][j] = 0.;
98  castorplus[1][j] = 0.;
99  castormin[1][j] = 0.;
100  castorplus[2][j] = 0.;
101  castormin[2][j] = 0.;
102  //castorplus[4][j] = 0.;
103  //castormin[4][j] = 0.;
104  }
105 
106  // declare properties vectors
107  vector<double> depthplus[16];
108  vector<double> depthmin[16];
109  vector<double> fhotplus[16];
110  vector<double> fhotmin[16];
111  vector<double> energyplus[16];
112  vector<double> energymin[16];
113  //vector<double> femplus [16];
114  //vector<double> femmin [16];
115 
116  for (int i = 0; i < 16; i++) {
117  depthplus[i].clear();
118  depthmin[i].clear();
119  fhotplus[i].clear();
120  fhotmin[i].clear();
121  energyplus[i].clear();
122  energymin[i].clear();
123  //femplus[i].clear();
124  //femmin[i].clear();
125  }
126 
127  //cout << "declared everything" << endl;
128 
129  // start particle loop
130  for (size_t i = 0; i < genParticles->size(); ++i) {
131  const Candidate& p = (*genParticles)[i];
132 
133  // select particles in castor
134  if (fabs(p.eta()) > 5.2 && fabs(p.eta()) < 6.6) {
135  //cout << "found particle in castor, start calculating" << endl;
136 
137  // declare energies
138  //double gaus_E = -1.;
139  double energy = -1.;
140  double emEnergy = 0.;
141  double hadEnergy = 0.;
142  double fhot = 0.;
143  double depth = 0.;
144  //double fem = 0.;
145 
146  // add energies - em: if particle is e- or gamma
147  if (p.pdgId() == 11 || p.pdgId() == 22) {
148  // calculate primary tower energy for electrons
149  while (energy < 0.) {
150  // apply energy smearing with gaussian random generator
151  TRandom3 r(0);
152  // use sigma/E parametrization from the full simulation
153  double mean = 1.0024 * p.energy() - 0.3859;
154  double sigma = 0.0228 * p.energy() + 2.1061;
155  energy = r.Gaus(mean, sigma);
156  }
157 
158  // calculate electromagnetic electron/photon energy leakage
159  double tmax;
160  double a;
161  double cte;
162  if (p.pdgId() == 11) {
163  cte = -0.5;
164  } else {
165  cte = 0.5;
166  }
167  tmax = 1.0 * (log(energy / 0.0015) + cte);
168  a = tmax * 0.5 + 1;
169  double leakage;
170  double x = 0.5 * 19.38;
171  leakage = energy - energy * Gamma(a, x);
172 
173  // add emEnergy
174  emEnergy = energy - leakage;
175  // add hadEnergy leakage
176  hadEnergy = leakage;
177 
178  // calculate EM depth from parametrization
179  double d0 = 0.2338 * pow(p.energy(), -0.1634);
180  double d1 = 5.4336 * pow(p.energy(), 0.2410) + 14408.1025;
181  double d2 = 1.4692 * pow(p.energy(), 0.1307) - 0.5216;
182  if (d0 < 0.)
183  d0 = abs(d0);
184 
185  TF1* fdepth =
186  new TF1("fdepth", "[0] * TMath::Exp(-0.5*( (x-[1])/[2] + TMath::Exp(-(x-[1])/[2])))", 14400., 14460.);
187  fdepth->SetParameters(d0, d1, d2);
188  depth = fdepth->GetRandom();
189  fdepth->Delete();
190  if (p.eta() < 0.)
191  depth = -1 * depth;
192 
193  } else {
194  // calculate primary tower energy for hadrons
195  while (energy < 0.) {
196  // apply energy smearing with gaussian random generator
197  TRandom3 r(0);
198  // use sigma/E parametrization from the full simulation
199  double mean = 0.8340 * p.energy() - 8.5054;
200  double sigma = 0.1595 * p.energy() + 3.1183;
201  energy = r.Gaus(mean, sigma);
202  }
203 
204  // add hadEnergy
205  hadEnergy = energy;
206 
207  // in the near future add fem parametrization
208 
209  // calculate depth for HAD particle from parametrization
210  double d0 = -0.000012 * p.energy() + 0.0661;
211  double d1 = 785.7524 * pow(p.energy(), 0.0262) + 13663.4262;
212  double d2 = 9.8748 * pow(p.energy(), 0.1720) + 37.0187;
213  if (d0 < 0.)
214  d0 = abs(d0);
215 
216  TF1* fdepth =
217  new TF1("fdepth", "[0] * TMath::Exp(-0.5*( (x-[1])/[2] + TMath::Exp(-(x-[1])/[2]) ))", 14400., 15500.);
218  fdepth->SetParameters(d0, d1, d2);
219  depth = fdepth->GetRandom();
220  fdepth->Delete();
221  if (p.eta() < 0.)
222  depth = -1 * depth;
223  }
224 
225  // make tower
226 
227  // set sector
228  int sector = -1;
229  for (int j = 0; j < 16; j++) {
230  double a = -M_PI + j * 0.3927;
231  double b = -M_PI + (j + 1) * 0.3927;
232  if ((p.phi() > a) && (p.phi() < b)) {
233  sector = j;
234  }
235  }
236 
237  // set eta
238  if (p.eta() > 0) {
239  castorplus[0][sector] = castorplus[0][sector] + energy;
240  castorplus[1][sector] = castorplus[1][sector] + emEnergy;
241  castorplus[2][sector] = castorplus[2][sector] + hadEnergy;
242 
243  depthplus[sector].push_back(depth);
244  fhotplus[sector].push_back(fhot);
245  energyplus[sector].push_back(energy);
246  //cout << "filled vectors" << endl;
247  //cout << "energyplus size = " << energyplus[sector].size() << endl;
248  //cout << "depthplus size = " << depthplus[sector].size() << endl;
249  //cout << "fhotplus size = " << fhotplus[sector].size() << endl;
250 
251  } else {
252  castormin[0][sector] = castormin[0][sector] + energy;
253  castormin[1][sector] = castormin[1][sector] + emEnergy;
254  castormin[2][sector] = castormin[2][sector] + hadEnergy;
255 
256  depthmin[sector].push_back(depth);
257  fhotmin[sector].push_back(fhot);
258  energymin[sector].push_back(energy);
259  //cout << "filled vectors" << endl;
260  }
261  }
262  }
263 
264  // add and substract pedestals/noise
265  for (int j = 0; j < 16; j++) {
266  double hadnoise = 0.;
267  double emnoise = 0.;
268  for (int i = 0; i < 12; i++) {
269  hadnoise = hadnoise + make_noise();
270  if (i < 2)
271  emnoise = emnoise + make_noise();
272  }
273 
274  hadnoise = hadnoise - 12 * 0.053;
275  emnoise = emnoise - 2 * 0.053;
276  if (hadnoise < 0.)
277  hadnoise = 0.;
278  if (emnoise < 0.)
279  emnoise = 0.;
280  double totnoise = hadnoise + emnoise;
281 
282  // add random noise
283  castorplus[0][j] = castorplus[0][j] + totnoise;
284  castormin[0][j] = castormin[0][j] + totnoise;
285  castorplus[1][j] = castorplus[1][j] + emnoise;
286  castormin[1][j] = castormin[1][j] + emnoise;
287  castorplus[2][j] = castorplus[2][j] + hadnoise;
288  castormin[2][j] = castormin[2][j] + hadnoise;
289 
290  //cout << "after constant substraction" << endl;
291  //cout << "total noise = " << castorplus[0][j] << " em noise = " << castorplus[1][j] << " had noise = " << castorplus[2][j] << endl;
292  //cout << "fem should be = " << castorplus[1][j]/castorplus[0][j] << endl;
293  }
294 
295  // store towers from castor arrays
296  // eta = 5.9
297  for (int j = 0; j < 16; j++) {
298  if (castorplus[0][j] != 0.) {
299  double fem = 0.;
300  fem = castorplus[1][j] / castorplus[0][j];
301  TowerPoint pt1(88.5, 5.9, castorplus[3][j]);
302  Point pt2(pt1);
303 
304  //cout << "fem became = " << castorplus[1][j]/castorplus[0][j] << endl;
305 
306  double depth_mean = 0.;
307  double fhot_mean = 0.;
308  double sum_energy = 0.;
309 
310  //cout << "energyplus size = " << energyplus[j].size()<< endl;
311  for (size_t p = 0; p < energyplus[j].size(); p++) {
312  depth_mean = depth_mean + depthplus[j][p] * energyplus[j][p];
313  fhot_mean = fhot_mean + fhotplus[j][p] * energyplus[j][p];
314  sum_energy = sum_energy + energyplus[j][p];
315  }
316  depth_mean = depth_mean / sum_energy;
317  fhot_mean = fhot_mean / sum_energy;
318  //cout << "computed depth/fhot" << endl;
319 
320  //std::vector<CastorCell> usedCells;
322  CastorTowers->push_back(reco::CastorTower(
323  castorplus[0][j], pt2, castorplus[1][j], castorplus[2][j], fem, depth_mean, fhot_mean, refvector));
324  }
325  }
326  // eta = -5.9
327  for (int j = 0; j < 16; j++) {
328  if (castormin[0][j] != 0.) {
329  double fem = 0.;
330  fem = castormin[1][j] / castormin[0][j];
331  TowerPoint pt1(88.5, -5.9, castormin[3][j]);
332  Point pt2(pt1);
333 
334  double depth_mean = 0.;
335  double fhot_mean = 0.;
336  double sum_energy = 0.;
337 
338  for (size_t p = 0; p < energymin[j].size(); p++) {
339  depth_mean = depth_mean + depthmin[j][p] * energymin[j][p];
340  fhot_mean = fhot_mean + fhotmin[j][p] * energymin[j][p];
341  sum_energy = sum_energy + energymin[j][p];
342  }
343  depth_mean = depth_mean / sum_energy;
344  fhot_mean = fhot_mean / sum_energy;
345 
346  //std::vector<CastorCell> usedCells;
348  CastorTowers->push_back(reco::CastorTower(
349  castormin[0][j], pt2, castormin[1][j], castormin[2][j], fem, depth_mean, fhot_mean, refvector));
350  }
351  }
352 
353  iEvent.put(std::move(CastorTowers));
354 }

References a, funct::abs(), b, d0, d1, LEDCalibrationChannels::depth, HCALHighEnergyHPDFilter_cfi::energy, hcaldqm::quantity::fdepth, genParticles2HepMC_cfi::genParticles, mps_fire::i, iEvent, dqmiolumiharvest::j, dqm-mbProfile::log, M_PI, make_noise(), SiStripPI::mean, eostools::move(), AlCaHLTBitMon_ParallelJobs::p, funct::pow(), HLT_FULL_cff::pt1, HLT_FULL_cff::pt2, edm::RefVector< C, T, F >::push_back(), alignCSCRings::r, tools::TF1, tmax, and x.

mps_fire.i
i
Definition: mps_fire.py:428
genParticles2HepMC_cfi.genParticles
genParticles
Definition: genParticles2HepMC_cfi.py:4
SiStripPI::mean
Definition: SiStripPayloadInspectorHelper.h:169
CastorFastTowerProducer::TowerPoint
ROOT::Math::RhoEtaPhiPoint TowerPoint
Definition: CastorFastTowerProducer.h:28
edm
HLT enums.
Definition: AlignableModifier.h:19
AlCaHLTBitMon_ParallelJobs.p
p
Definition: AlCaHLTBitMon_ParallelJobs.py:153
hcaldqm::quantity::fdepth
Definition: DetectorQuantity.h:16
CastorFastTowerProducer::make_noise
double make_noise()
Definition: CastorFastTowerProducer.cc:356
DDAxes::x
edm::RefVector
Definition: EDProductfwd.h:27
reco
fixed size matrix
Definition: AlignmentAlgorithmBase.h:45
tools.TF1
TF1
Definition: tools.py:23
edm::Handle
Definition: AssociativeIterator.h:50
tmax
static const double tmax[3]
Definition: CastorTimeSlew.cc:7
HLT_FULL_cff.pt1
pt1
Definition: HLT_FULL_cff.py:9936
HCALHighEnergyHPDFilter_cfi.energy
energy
Definition: HCALHighEnergyHPDFilter_cfi.py:5
b
double b
Definition: hdecay.h:118
LEDCalibrationChannels.depth
depth
Definition: LEDCalibrationChannels.py:65
Point
Structure Point Contains parameters of Gaussian fits to DMRs.
Definition: DMRtrends.cc:57
a
double a
Definition: hdecay.h:119
diffTwoXMLs.r2
r2
Definition: diffTwoXMLs.py:73
iEvent
int iEvent
Definition: GenABIO.cc:224
M_PI
#define M_PI
Definition: BXVectorInputProducer.cc:49
HLT_FULL_cff.pt2
pt2
Definition: HLT_FULL_cff.py:9938
edm::RefVector::push_back
void push_back(value_type const &ref)
Add a Ref<C, T> to the RefVector.
Definition: RefVector.h:67
reco::Candidate
Definition: Candidate.h:27
alignCSCRings.r
r
Definition: alignCSCRings.py:93
eostools.move
def move(src, dest)
Definition: eostools.py:511
std
Definition: JetResolutionObject.h:76
reco::CastorTower
Definition: CastorTower.h:26
dqm-mbProfile.log
log
Definition: dqm-mbProfile.py:17
funct::pow
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
mps_fire.result
result
Definition: mps_fire.py:311
funct::abs
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
dqmiolumiharvest.j
j
Definition: dqmiolumiharvest.py:66
d0
static constexpr float d0
Definition: L1EGammaCrystalsEmulatorProducer.cc:84
reco::CastorTowerCollection
std::vector< CastorTower > CastorTowerCollection
collection of CastorTower objects
Definition: CastorTower.h:137
d1
static constexpr float d1
Definition: L1EGammaCrystalsEmulatorProducer.cc:84