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ElectronEnergyCorrector Class Reference

#include <ElectronEnergyCorrector.h>

Public Member Functions

void classBasedParameterizationEnergy (reco::GsfElectron &, const reco::BeamSpot &bs)
 
void classBasedParameterizationUncertainty (reco::GsfElectron &)
 
 ElectronEnergyCorrector (EcalClusterFunctionBaseClass *crackCorrectionFunction)
 
void simpleParameterizationUncertainty (reco::GsfElectron &)
 

Private Member Functions

float fBremEta (float sigmaPhiSigmaEta, float eta, int algorithm, reco::GsfElectron::Classification cl) const
 
float fEnergy (float e, int algorithm, reco::GsfElectron::Classification cl) const
 
float fEt (float et, int algorithm, reco::GsfElectron::Classification cl) const
 
float fEta (float energy, float eta, int algorithm) const
 
double fEtaBarrelBad (double scEta) const
 
double fEtaBarrelGood (double scEta) const
 
double fEtaEndcapBad (double scEta) const
 
double fEtaEndcapGood (double scEta) const
 

Private Attributes

EcalClusterFunctionBaseClasscrackCorrectionFunction_
 

Detailed Description

Definition at line 10 of file ElectronEnergyCorrector.h.

Constructor & Destructor Documentation

ElectronEnergyCorrector::ElectronEnergyCorrector ( EcalClusterFunctionBaseClass crackCorrectionFunction)
inline

Member Function Documentation

void ElectronEnergyCorrector::classBasedParameterizationEnergy ( reco::GsfElectron electron,
const reco::BeamSpot bs 
)

Definition at line 56 of file ElectronEnergyCorrector.cc.

References reco::GsfElectron::classification(), corr, crackCorrectionFunction_, stringResolutionProvider_cfi::et, fBremEta(), fEnergy(), fEt(), fEta(), reco::GsfElectron::GAP, EcalClusterFunctionBaseClass::getValue(), reco::GsfElectron::isEB(), reco::GsfElectron::isEcalEnergyCorrected(), reco::GsfElectron::isEE(), mathSSE::return(), reco::GsfElectron::setCorrectedEcalEnergy(), reco::GsfElectron::superCluster(), and reco::GsfElectron::UNKNOWN.

Referenced by GsfElectronAlgo::createElectron(), ElectronEnergyCorrector(), and simpleParameterizationUncertainty().

57  {
58  if (electron.isEcalEnergyCorrected())
59  {
60  edm::LogWarning("ElectronEnergyCorrector::classBasedParameterizationEnergy")<<"already done" ;
61  return ;
62  }
63 
65  if ( (elClass <= reco::GsfElectron::UNKNOWN) ||
66  (elClass>reco::GsfElectron::GAP) )
67  {
68  edm::LogWarning("ElectronEnergyCorrector::classBasedParameterizationEnergy")<<"unexpected classification" ;
69  return ;
70  }
71 
72  // new corrections from N. Chanon et al., taken from EcalClusterCorrectionObjectSpecific.cc
73  float corr = 1.;
74  float corr2 = 1.;
75  float energy = electron.superCluster()->energy() ;
76 
77  //int subdet = electron.superCluster()->seed()->hitsAndFractions()[0].first.subdetId();
78 
79  if (electron.isEB())
80  {
81  float cetacorr = fEta(electron.superCluster()->rawEnergy(), electron.superCluster()->eta(), 0)/electron.superCluster()->rawEnergy();
82  energy = electron.superCluster()->rawEnergy()*cetacorr; //previously in CMSSW
83  //energy = superCluster.rawEnergy()*fEta(e5x5, superCluster.seed()->eta(), 0)/e5x5;
84  }
85  else if (electron.isEE())
86  {
87  energy = electron.superCluster()->rawEnergy()+electron.superCluster()->preshowerEnergy();
88  }
89  else
90  { edm::LogWarning("ElectronEnergyCorrector::classBasedParameterizationEnergy")<<"nor barrel neither endcap electron !" ; }
91 
92  corr = fBremEta(electron.superCluster()->phiWidth()/electron.superCluster()->etaWidth(), electron.superCluster()->eta(), 0,elClass);
93 
94  float et = energy*TMath::Sin(2*TMath::ATan(TMath::Exp(-electron.superCluster()->eta())))/corr;
95 
96  if (electron.isEB()) { corr2 = corr * fEt(et, 0,elClass) ; }
97  else if (electron.isEE()) { corr2 = corr * fEnergy(energy/corr, 1,elClass) ; }
98  else { edm::LogWarning("ElectronEnergyCorrector::classBasedParameterizationEnergy")<<"nor barrel neither endcap electron !" ; }
99 
100  float newEnergy = energy/corr2;
101 
102  // cracks
103  double crackcor = 1. ;
105  cIt = electron.superCluster()->clustersBegin() ;
106  cIt != electron.superCluster()->clustersEnd() ;
107  ++cIt )
108  {
109  const reco::CaloClusterPtr cc = *cIt ;
110  crackcor *=
111  ( electron.superCluster()->rawEnergy()
112  + cc->energy()*(crackCorrectionFunction_->getValue(*cc)-1.) )
113  / electron.superCluster()->rawEnergy() ;
114  }
115  newEnergy *= crackcor ;
116 
117  // register final value
118  electron.setCorrectedEcalEnergy(newEnergy) ;
119 
120  }
bool isEcalEnergyCorrected() const
Definition: GsfElectron.h:833
bool isEE() const
Definition: GsfElectron.h:353
bool isEB() const
Definition: GsfElectron.h:352
float fBremEta(float sigmaPhiSigmaEta, float eta, int algorithm, reco::GsfElectron::Classification cl) const
return((rh^lh)&mask)
virtual float getValue(const reco::BasicCluster &, const EcalRecHitCollection &) const =0
JetCorrectorParameters corr
Definition: classes.h:5
float fEt(float et, int algorithm, reco::GsfElectron::Classification cl) const
Classification classification() const
Definition: GsfElectron.h:757
et
define resolution functions of each parameter
float fEnergy(float e, int algorithm, reco::GsfElectron::Classification cl) const
void setCorrectedEcalEnergy(float newEnergy)
Definition: GsfElectron.cc:182
SuperClusterRef superCluster() const override
reference to a SuperCluster
Definition: GsfElectron.h:184
float fEta(float energy, float eta, int algorithm) const
EcalClusterFunctionBaseClass * crackCorrectionFunction_
void ElectronEnergyCorrector::classBasedParameterizationUncertainty ( reco::GsfElectron electron)

Definition at line 20 of file ElectronEnergyCorrector.cc.

References reco::GsfElectron::classification(), EnergyUncertaintyElectronSpecific::computeElectronEnergyUncertainty(), reco::GsfElectron::correctedEcalEnergy(), energyError(), reco::GsfElectron::setCorrectedEcalEnergyError(), and reco::GsfElectron::superCluster().

Referenced by GsfElectronAlgo::createElectron(), and ElectronEnergyCorrector().

21  {
23  double energyError = 999. ;
24  double ecalEnergy = electron.correctedEcalEnergy() ;
25  double eleEta = electron.superCluster()->eta() ;
26  double brem = electron.superCluster()->etaWidth()/electron.superCluster()->phiWidth() ;
27  energyError = uncertainty.computeElectronEnergyUncertainty(electron.classification(),eleEta,brem,ecalEnergy) ;
28  electron.setCorrectedEcalEnergyError(energyError) ;
29  }
void setCorrectedEcalEnergyError(float newEnergyError)
Definition: GsfElectron.cc:179
float correctedEcalEnergy() const
Definition: GsfElectron.h:834
Classification classification() const
Definition: GsfElectron.h:757
double computeElectronEnergyUncertainty(reco::GsfElectron::Classification c, double eta, double brem, double energy)
SuperClusterRef superCluster() const override
reference to a SuperCluster
Definition: GsfElectron.h:184
float energyError(float E, float *par)
float ElectronEnergyCorrector::fBremEta ( float  sigmaPhiSigmaEta,
float  eta,
int  algorithm,
reco::GsfElectron::Classification  cl 
) const
private

Definition at line 158 of file ElectronEnergyCorrector.cc.

References Abs(), GetRecoTauVFromDQM_MC_cff::cl, reco::GsfElectron::GAP, RecoTauPiZeroBuilderPlugins_cfi::par0, and RecoTauPiZeroBuilderPlugins_cfi::par1.

Referenced by classBasedParameterizationEnergy(), ElectronEnergyCorrector(), and fEta().

159  {
160  // corrections for electrons
161  if (algorithm!=0)
162  {
163  edm::LogWarning("ElectronEnergyCorrector::fBremEta")<<"algorithm should be 0 for electrons !" ;
164  return 1. ;
165  }
166 
167  const float etaCrackMin = 1.44 ;
168  const float etaCrackMax = 1.56 ;
169 
170  //STD
171  const int nBinsEta = 14 ;
172  float leftEta[nBinsEta] = { 0.02, 0.25, 0.46, 0.81, 0.91, 1.01, 1.16, etaCrackMax, 1.653, 1.8, 2.0, 2.2, 2.3, 2.4 } ;
173  float rightEta[nBinsEta] = { 0.25, 0.42, 0.77, 0.91, 1.01, 1.13, etaCrackMin, 1.653, 1.8, 2.0, 2.2, 2.3, 2.4, 2.5 } ;
174 
175  // eta = 0
176  if ( TMath::Abs(eta) < leftEta[0] ) { eta = 0.02 ; }
177 
178  // outside acceptance
179  if ( TMath::Abs(eta) >= rightEta[nBinsEta-1] ) { eta = 2.49 ; } //if (DBG) std::cout << " WARNING [applyScCorrections]: TMath::Abs(eta) >= rightEta[nBinsEta-1] " << std::endl;}
180 
181  int tmpEta = -1 ;
182  for (int iEta = 0; iEta < nBinsEta; ++iEta)
183  {
184  if ( leftEta[iEta] <= TMath::Abs(eta) && TMath::Abs(eta) <rightEta[iEta] )
185  { tmpEta = iEta ; }
186  }
187 
188  float xcorr[nBinsEta][reco::GsfElectron::GAP+1] =
189  {
190  { 1.00227, 1.00227, 1.00227, 1.00227, 1.00227 },
191  { 1.00252, 1.00252, 1.00252, 1.00252, 1.00252 },
192  { 1.00225, 1.00225, 1.00225, 1.00225, 1.00225 },
193  { 1.00159, 1.00159, 1.00159, 1.00159, 1.00159 },
194  { 0.999475, 0.999475, 0.999475, 0.999475, 0.999475 },
195  { 0.997203, 0.997203, 0.997203, 0.997203, 0.997203 },
196  { 0.993886, 0.993886, 0.993886, 0.993886, 0.993886 },
197  { 0.971262, 0.971262, 0.971262, 0.971262, 0.971262 },
198  { 0.975922, 0.975922, 0.975922, 0.975922, 0.975922 },
199  { 0.979087, 0.979087, 0.979087, 0.979087, 0.979087 },
200  { 0.98495, 0.98495, 0.98495, 0.98495, 0.98495 },
201  { 0.98781, 0.98781, 0.98781, 0.98781, 0.98781 },
202  { 0.989546, 0.989546, 0.989546, 0.989546, 0.989546 },
203  { 0.989638, 0.989638, 0.989638, 0.989638, 0.989638 }
204  } ;
205 
206  float par0[nBinsEta][reco::GsfElectron::GAP+1] =
207  {
208  { 0.994949, 1.00718, 1.00718, 1.00556, 1.00718 },
209  { 1.009, 1.00713, 1.00713, 1.00248, 1.00713 },
210  { 0.999395, 1.00641, 1.00641, 1.00293, 1.00641 },
211  { 0.988662, 1.00761, 1.001, 0.99972, 1.00761 },
212  { 0.998443, 1.00682, 1.001, 1.00282, 1.00682 },
213  { 1.00285, 1.0073, 1.001, 1.00396, 1.0073 },
214  { 0.993053, 1.00462, 1.01341, 1.00184, 1.00462 },
215  { 1.10561, 0.972798, 1.02835, 0.995218, 0.972798 },
216  { 0.893741, 0.981672, 0.98982, 1.01712, 0.981672 },
217  { 0.911123, 0.98251, 1.03466, 1.00824, 0.98251 },
218  { 0.981931, 0.986123, 0.954295, 1.0202, 0.986123 },
219  { 0.905634, 0.990124, 0.928934, 0.998492, 0.990124 },
220  { 0.919343, 0.990187, 0.967526, 0.963923, 0.990187 },
221  { 0.844783, 0.99372, 0.923808, 0.953001, 0.99372 }
222  } ;
223 
224  float par1[nBinsEta][reco::GsfElectron::GAP+1] =
225  {
226  { 0.0111034, -0.00187886, -0.00187886, -0.00289304, -0.00187886 },
227  { -0.00969012, -0.00227574, -0.00227574, -0.00182187, -0.00227574 },
228  { 0.00389454, -0.00259935, -0.00259935, -0.00211059, -0.00259935 },
229  { 0.017095, -0.00433692, -0.00302335, -0.00241385, -0.00433692 },
230  { -0.00049009, -0.00551324, -0.00302335, -0.00532352, -0.00551324 },
231  { -0.00252723, -0.00799669, -0.00302335, -0.00823109, -0.00799669 },
232  { 0.00332567, -0.00870057, -0.0170581, -0.011482, -0.00870057 },
233  { -0.213285, -0.000771577, -0.036007, -0.0187526, -0.000771577 },
234  { 0.1741, -0.00202028, -0.0233995, -0.0302066, -0.00202028 },
235  { 0.152794, 0.00441308, -0.0468563, -0.0158817, 0.00441308 },
236  { 0.0351465, 0.00832913, 0.0358028, -0.0233262, 0.00832913 },
237  { 0.185781, 0.00742879, 0.08858, 0.00568078, 0.00742879 },
238  { 0.153088, 0.0094608, 0.0489979, 0.0491897, 0.0094608 },
239  { 0.296681, 0.00560406, 0.106492, 0.0652007, 0.00560406 }
240  } ;
241 
242  float par2[nBinsEta][reco::GsfElectron::GAP+1] =
243  {
244  { -0.00330844, 0, 0, 5.62441e-05, 0 },
245  { 0.00329373, 0, 0, -0.000113883, 0 },
246  { -0.00104661, 0, 0, -0.000152794, 0 },
247  { -0.0060409, 0, -0.000257724, -0.000202099, 0 },
248  { -0.000742866, 0, -0.000257724, -2.06003e-05, 0 },
249  { -0.00205425, 0, -0.000257724, 3.84179e-05, 0 },
250  { -0.00350757, 0, 0.000590483, 0.000323723, 0 },
251  { 0.0794596, -0.00276696, 0.00205854, 0.000356716, -0.00276696 },
252  { -0.092436, -0.00471028, 0.00062096, 0.00088347, -0.00471028 },
253  { -0.0855029, -0.00809139, 0.00284102, -0.00366903, -0.00809139 },
254  { -0.0306209, -0.00944584, -0.0145892, -0.00176969, -0.00944584 },
255  { -0.0996414, -0.00960462, -0.0328264, -0.00983844, -0.00960462 },
256  { -0.0784107, -0.010172, -0.0256722, -0.0215133, -0.010172 },
257  { -0.145815, -0.00943169, -0.0414525, -0.027087, -0.00943169 }
258  } ;
259 
260  float sigmaPhiSigmaEtaMin[reco::GsfElectron::GAP+1] = { 0.8, 0.8, 0.8, 0.8, 0.8 } ;
261  float sigmaPhiSigmaEtaMax[reco::GsfElectron::GAP+1] = { 5., 5., 5., 5., 5. } ;
262  float sigmaPhiSigmaEtaFit[reco::GsfElectron::GAP+1] = { 1.2, 1.2, 1.2, 1.2, 1.2 } ;
263 
264  // extra protections
265  // fix sigmaPhiSigmaEta boundaries
266  if ( sigmaPhiSigmaEta < sigmaPhiSigmaEtaMin[cl] )
267  { sigmaPhiSigmaEta = sigmaPhiSigmaEtaMin[cl] ; }
268  if ( sigmaPhiSigmaEta > sigmaPhiSigmaEtaMax[cl] )
269  { sigmaPhiSigmaEta = sigmaPhiSigmaEtaMax[cl] ; }
270 
271  // In eta cracks/gaps
272  if ( tmpEta == -1 ) // need to interpolate
273  {
274  float tmpInter = 1 ;
275  for ( int iEta = 0 ; iEta < nBinsEta-1 ; ++iEta )
276  {
277  if ( rightEta[iEta] <= TMath::Abs(eta) && TMath::Abs(eta) <leftEta[iEta+1] )
278  {
279  if ( sigmaPhiSigmaEta >= sigmaPhiSigmaEtaFit[cl] )
280  {
281  tmpInter =
282  ( par0[iEta][cl] +
283  sigmaPhiSigmaEta*par1[iEta][cl] +
284  sigmaPhiSigmaEta*sigmaPhiSigmaEta*par2[iEta][cl] +
285  par0[iEta+1][cl] +
286  sigmaPhiSigmaEta*par1[iEta+1][cl] +
287  sigmaPhiSigmaEta*sigmaPhiSigmaEta*par2[iEta+1][cl] ) / 2. ;
288  }
289  else tmpInter = (xcorr[iEta][cl] + xcorr[iEta+1][cl])/2. ;
290  }
291  }
292  return tmpInter ;
293  }
294 
295  if (sigmaPhiSigmaEta >= sigmaPhiSigmaEtaFit[cl])
296  { return par0[tmpEta][cl] + sigmaPhiSigmaEta*par1[tmpEta][cl] + sigmaPhiSigmaEta*sigmaPhiSigmaEta*par2[tmpEta][cl] ; }
297  else
298  { return xcorr[tmpEta][cl] ; }
299 
300  return 1. ;
301  }
T Abs(T a)
Definition: MathUtil.h:49
float ElectronEnergyCorrector::fEnergy ( float  e,
int  algorithm,
reco::GsfElectron::Classification  cl 
) const
private

Definition at line 342 of file ElectronEnergyCorrector.cc.

References GetRecoTauVFromDQM_MC_cff::cl, JetChargeProducer_cfi::exp, reco::GsfElectron::GAP, RecoTauPiZeroBuilderPlugins_cfi::par0, and RecoTauPiZeroBuilderPlugins_cfi::par1.

Referenced by classBasedParameterizationEnergy(), and ElectronEnergyCorrector().

343  {
344  if (algorithm==0) // Electrons EB
345  { return 1. ; }
346  else if (algorithm==1) // Electrons EE
347  {
348  float par0[reco::GsfElectron::GAP+1] = { 400, 400, 400, 400, 400 } ;
349  float par1[reco::GsfElectron::GAP+1] = { 0.999545, 0.982475, 0.986217, 0.996763, 0.982475 } ;
350  float par2[reco::GsfElectron::GAP+1] = { 1.26568e-05, 4.95413e-05, 5.02161e-05, 2.8485e-06, 4.95413e-05 } ;
351  float par3[reco::GsfElectron::GAP+1] = { 0.0696757, 0.16886, 0.115317, 0.12098, 0.16886 } ;
352  float par4[reco::GsfElectron::GAP+1] = { -54.3468, -30.1517, -26.3805, -62.0538, -30.1517 } ;
353 
354  if ( E > par0[cl] ) { E = par0[cl] ; }
355  if ( E < 0 ) { return 1. ; }
356  if ( 0 <= E && E <= par0[cl] ) { return (par1[cl] + E*par2[cl] )*(1- par3[cl]*exp(E/par4[cl] )) ; }
357  }
358  else
359  { edm::LogWarning("ElectronEnergyCorrector::fEnergy")<<"algorithm should be 0 or 1 for electrons !" ; }
360  return 1.;
361  }
float ElectronEnergyCorrector::fEt ( float  et,
int  algorithm,
reco::GsfElectron::Classification  cl 
) const
private

Definition at line 303 of file ElectronEnergyCorrector.cc.

References GetRecoTauVFromDQM_MC_cff::cl, JetChargeProducer_cfi::exp, and reco::GsfElectron::GAP.

Referenced by classBasedParameterizationEnergy(), and ElectronEnergyCorrector().

304  {
305  if (algorithm==0) //Electrons EB
306  {
307  const float parClassIndep[5] = { 0.97213, 0.999528, 5.61192e-06, 0.0143269, -17.1776 } ;
308  const float par[reco::GsfElectron::GAP+1][5] =
309  {
310  { 0.974327, 0.996127, 5.99401e-05, 0.159813, -3.80392 },
311  { 0.97213, 0.999528, 5.61192e-06, 0.0143269, -17.1776 },
312  { 0.940666, 0.988894, 0.00017474, 0.25603, -4.58153 },
313  { 0.969526, 0.98572, 0.000193842, 4.21548, -1.37159 },
314  { parClassIndep[0], parClassIndep[1], parClassIndep[2], parClassIndep[3], parClassIndep[4] }
315  } ;
316  if ( ET > 200 ) { ET = 200 ; }
317  if ( ET > 100 ) { return (parClassIndep[1]+ET*parClassIndep[2]) * (1-parClassIndep[3]*exp(ET/parClassIndep[4])) ; }
318  if ( ET >= 10 ) { return (par[cl][1]+ET*par[cl][2]) * (1-par[cl][3]*exp(ET/par[cl][4])) ; }
319  if ( ET >=5 ) { return par[cl][0] ; }
320  return 1. ;
321  }
322  else if (algorithm==1) //Electrons EE
323  {
324  float par[reco::GsfElectron::GAP+1][5] =
325  {
326  { 0.930081, 0.996683, 3.54079e-05, 0.0460187, -23.2461 },
327  { 0.930081, 0.996683, 3.54079e-05, 0.0460187, -23.2461 },
328  { 0.930081, 0.996683, 3.54079e-05, 0.0460187, -23.2461 },
329  { 0.930081, 0.996683, 3.54079e-05, 0.0460187, -23.2461 },
330  { 0.930081, 0.996683, 3.54079e-05, 0.0460187, -23.2461 }
331  };
332  if ( ET > 200 ) { ET = 200 ; }
333  if ( ET < 5 ) { return 1. ; }
334  if ( 5 <= ET && ET < 10 ) { return par[cl][0] ; }
335  if ( 10 <= ET && ET <= 200 ) { return ( par[cl][1] + ET*par[cl][2])*(1-par[cl][3]*exp(ET/par[cl][4])) ; }
336  }
337  else
338  { edm::LogWarning("ElectronEnergyCorrector::fEt")<<"algorithm should be 0 or 1 for electrons !" ; }
339  return 1. ;
340  }
#define ET
float ElectronEnergyCorrector::fEta ( float  energy,
float  eta,
int  algorithm 
) const
private

Definition at line 127 of file ElectronEnergyCorrector.cc.

References fBremEta(), and p1.

Referenced by classBasedParameterizationEnergy(), and ElectronEnergyCorrector().

128 {
129 
130  // corrections for electrons
131  if (algorithm!=0) {
132  edm::LogWarning("ElectronEnergyCorrector::fEta")<<"algorithm should be 0 for electrons !" ;
133  return energy;
134  }
135  //std::cout << "fEta function" << std::endl;
136 
137  // this correction is setup only for EB
138  if ( algorithm != 0 ) return energy;
139 
140  float ieta = fabs(eta)*(5/0.087);
141  // bypass the DB reading for the time being
142  //float p0 = (params_->params())[0]; // should be 40.2198
143  //float p1 = (params_->params())[1]; // should be -3.03103e-6
144  float p0 = 40.2198 ;
145  float p1 = -3.03103e-6 ;
146 
147  //std::cout << "ieta=" << ieta << std::endl;
148 
149  float correctedEnergy = energy;
150  if ( ieta < p0 ) correctedEnergy = energy;
151  else correctedEnergy = energy/(1.0 + p1*(ieta-p0)*(ieta-p0));
152  //std::cout << "ECEC fEta = " << correctedEnergy << std::endl;
153  return correctedEnergy;
154 
155  }
double p1[4]
Definition: TauolaWrapper.h:89
double ElectronEnergyCorrector::fEtaBarrelBad ( double  scEta) const
private

Definition at line 381 of file ElectronEnergyCorrector.cc.

References funct::abs(), p1, p2, p3, p4, and x.

Referenced by ElectronEnergyCorrector().

382  {
383  // f(eta) for the class = 30 (estimated from 1Mevt single e sample)
384  // Ivica's new corrections 01/06
385  float p0 = 9.99063e-01;
386  float p1 = -2.63341e-02;
387  float p2 = 5.16054e-02;
388  float p3 = -4.95976e-02;
389  float p4 = 3.62304e-03;
390  double x = (double) std::abs(scEta) ;
391  return p0 + p1*x + p2*x*x + p3*x*x*x + p4*x*x*x*x ;
392  }
double p4[4]
Definition: TauolaWrapper.h:92
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double p2[4]
Definition: TauolaWrapper.h:90
double p1[4]
Definition: TauolaWrapper.h:89
double p3[4]
Definition: TauolaWrapper.h:91
double ElectronEnergyCorrector::fEtaBarrelGood ( double  scEta) const
private

Definition at line 368 of file ElectronEnergyCorrector.cc.

References funct::abs(), p1, p2, p3, p4, and x.

Referenced by ElectronEnergyCorrector().

369  {
370  // f(eta) for the first 3 classes (0, 10 and 20) (estimated from 1Mevt single e sample)
371  // Ivica's new corrections 01/06
372  float p0 = 1.00149e+00 ;
373  float p1 = -2.06622e-03 ;
374  float p2 = -1.08793e-02 ;
375  float p3 = 1.54392e-02 ;
376  float p4 = -1.02056e-02 ;
377  double x = (double) std::abs(scEta) ;
378  return p0 + p1*x + p2*x*x + p3*x*x*x + p4*x*x*x*x ;
379  }
double p4[4]
Definition: TauolaWrapper.h:92
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double p2[4]
Definition: TauolaWrapper.h:90
double p1[4]
Definition: TauolaWrapper.h:89
double p3[4]
Definition: TauolaWrapper.h:91
double ElectronEnergyCorrector::fEtaEndcapBad ( double  scEta) const
private

Definition at line 407 of file ElectronEnergyCorrector.cc.

References funct::abs(), p1, p2, p3, p4, and x.

Referenced by ElectronEnergyCorrector().

408  {
409  // f(eta) for the class = 130-134
410  // Ivica's new corrections 01/06
411  float p0 = -4.25221e+00 ;
412  float p1 = 1.01936e+01 ;
413  float p2 = -7.48247e+00 ;
414  float p3 = 2.45520e+00 ;
415  float p4 = -3.02872e-01 ;
416  double x = (double) std::abs(scEta);
417  return p0 + p1*x + p2*x*x + p3*x*x*x + p4*x*x*x*x ;
418  }
double p4[4]
Definition: TauolaWrapper.h:92
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double p2[4]
Definition: TauolaWrapper.h:90
double p1[4]
Definition: TauolaWrapper.h:89
double p3[4]
Definition: TauolaWrapper.h:91
double ElectronEnergyCorrector::fEtaEndcapGood ( double  scEta) const
private

Definition at line 394 of file ElectronEnergyCorrector.cc.

References funct::abs(), p1, p2, p3, p4, and x.

Referenced by ElectronEnergyCorrector().

395  {
396  // f(eta) for the first 3 classes (100, 110 and 120)
397  // Ivica's new corrections 01/06
398  float p0 = -8.51093e-01 ;
399  float p1 = 3.54266e+00 ;
400  float p2 = -2.59288e+00 ;
401  float p3 = 8.58945e-01 ;
402  float p4 = -1.07844e-01 ;
403  double x = (double) std::abs(scEta) ;
404  return p0 + p1*x + p2*x*x + p3*x*x*x + p4*x*x*x*x ;
405  }
double p4[4]
Definition: TauolaWrapper.h:92
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double p2[4]
Definition: TauolaWrapper.h:90
double p1[4]
Definition: TauolaWrapper.h:89
double p3[4]
Definition: TauolaWrapper.h:91
void ElectronEnergyCorrector::simpleParameterizationUncertainty ( reco::GsfElectron electron)

Definition at line 34 of file ElectronEnergyCorrector.cc.

References classBasedParameterizationEnergy(), reco::GsfElectron::correctedEcalEnergy(), energyError(), relativeConstraints::error, reco::GsfElectron::isEB(), reco::GsfElectron::isEE(), and reco::GsfElectron::setCorrectedEcalEnergyError().

Referenced by GsfElectronAlgo::createElectron(), and ElectronEnergyCorrector().

35  {
36  double error = 999. ;
37  double ecalEnergy = electron.correctedEcalEnergy() ;
38 
39  if (electron.isEB())
40  {
41  float parEB[3] = { 5.24e-02, 2.01e-01, 1.00e-02} ;
42  error = ecalEnergy*energyError(ecalEnergy,parEB) ;
43  }
44  else if (electron.isEE())
45  {
46  float parEE[3] = { 1.46e-01, 9.21e-01, 1.94e-03} ;
47  error = ecalEnergy*energyError(ecalEnergy,parEE) ;
48  }
49  else
50  { edm::LogWarning("ElectronEnergyCorrector::simpleParameterizationUncertainty")<<"nor barrel neither endcap electron !" ; }
51 
52  electron.setCorrectedEcalEnergyError(error) ;
53  }
bool isEE() const
Definition: GsfElectron.h:353
bool isEB() const
Definition: GsfElectron.h:352
void setCorrectedEcalEnergyError(float newEnergyError)
Definition: GsfElectron.cc:179
float correctedEcalEnergy() const
Definition: GsfElectron.h:834
float energyError(float E, float *par)

Member Data Documentation

EcalClusterFunctionBaseClass* ElectronEnergyCorrector::crackCorrectionFunction_
private

Definition at line 36 of file ElectronEnergyCorrector.h.

Referenced by classBasedParameterizationEnergy().