Go to the documentation of this file.00001 #include "RecoLocalCalo/HcalRecAlgos/interface/HcalHF_S9S1algorithm.h"
00002 #include "RecoLocalCalo/HcalRecAlgos/interface/HcalCaloFlagLabels.h"
00003 #include "FWCore/MessageLogger/interface/MessageLogger.h"
00004 #include "Geometry/HcalTowerAlgo/src/HcalHardcodeGeometryData.h"
00005 #include "RecoLocalCalo/HcalRecAlgos/interface/HcalSeverityLevelComputer.h"
00006 #include "RecoLocalCalo/HcalRecAlgos/interface/HcalSeverityLevelComputerRcd.h"
00007 #include "CondFormats/HcalObjects/interface/HcalChannelQuality.h"
00008
00009 #include <algorithm>
00010 #include <cmath>
00011 #include <iostream>
00012
00013 HcalHF_S9S1algorithm::HcalHF_S9S1algorithm()
00014 {
00015
00016 std::vector<double> blank;
00017 blank.clear();
00018 blank.push_back(0);
00019 std::vector<double> EnergyDefault;
00020 EnergyDefault.clear();
00021 EnergyDefault.push_back(50);
00022
00023
00024 LongSlopes.clear();
00025 ShortSlopes.clear();
00026 for (int i=29;i<=41;++i)
00027 {
00028 LongSlopes.push_back(0);
00029 ShortSlopes.push_back(0);
00030 }
00031 LongEnergyThreshold.clear();
00032 LongETThreshold.clear();
00033 ShortEnergyThreshold.clear();
00034 ShortETThreshold.clear();
00035 for (int i=29;i<=41;++i)
00036 {
00037 LongEnergyThreshold.push_back(EnergyDefault[0]);
00038 LongETThreshold.push_back(blank[0]);
00039 ShortEnergyThreshold.push_back(EnergyDefault[0]);
00040 ShortETThreshold.push_back(blank[0]);
00041 }
00042 HcalAcceptSeverityLevel_=0;
00043 isS8S1_=false;
00044 }
00045
00046
00047 HcalHF_S9S1algorithm::HcalHF_S9S1algorithm(std::vector<double> short_optimumSlope,
00048 std::vector<double> short_Energy,
00049 std::vector<double> short_ET,
00050 std::vector<double> long_optimumSlope,
00051 std::vector<double> long_Energy,
00052 std::vector<double> long_ET,
00053 int HcalAcceptSeverityLevel,
00054 bool isS8S1)
00055
00056 {
00057
00058
00059
00060
00061 LongSlopes=long_optimumSlope;
00062 ShortSlopes=short_optimumSlope;
00063
00064 while (LongSlopes.size()<13)
00065 LongSlopes.push_back(0);
00066 while (ShortSlopes.size()<13)
00067 ShortSlopes.push_back(0);
00068
00069
00070 LongEnergyThreshold.clear();
00071 LongETThreshold.clear();
00072 ShortEnergyThreshold.clear();
00073 ShortETThreshold.clear();
00074 LongEnergyThreshold=long_Energy;
00075 LongETThreshold=long_ET;
00076 ShortEnergyThreshold=short_Energy;
00077 ShortETThreshold=short_ET;
00078
00079 HcalAcceptSeverityLevel_=HcalAcceptSeverityLevel;
00080 isS8S1_=isS8S1;
00081 }
00082
00083 HcalHF_S9S1algorithm::~HcalHF_S9S1algorithm(){}
00084
00085
00086 void HcalHF_S9S1algorithm::HFSetFlagFromS9S1(HFRecHit& hf,
00087 HFRecHitCollection& rec,
00088 HcalChannelQuality* myqual,
00089 const HcalSeverityLevelComputer* mySeverity)
00090
00091 {
00092 int ieta=hf.id().ieta();
00093 int depth=hf.id().depth();
00094 int iphi=hf.id().iphi();
00095 double fEta = 0.5*(theHFEtaBounds[abs(ieta)-29] + theHFEtaBounds[abs(ieta)-28]);
00096 double energy=hf.energy();
00097 double ET = energy/fabs(cosh(fEta));
00098
00099
00100 double ETthresh=0, Energythresh=0;
00101 if (depth==1)
00102 {
00103 Energythresh = LongEnergyThreshold[abs(ieta)-29];
00104 ETthresh = LongETThreshold[abs(ieta)-29];
00105 }
00106 else if (depth==2)
00107 {
00108 Energythresh = ShortEnergyThreshold[abs(ieta)-29];
00109 ETthresh = ShortETThreshold[abs(ieta)-29];
00110 }
00111 if (energy<Energythresh || ET < ETthresh)
00112 return;
00113
00114
00115
00116 if (depth==2 && abs(ieta)>29 && isS8S1_)
00117 {
00118 double EL=0;
00119
00120 HcalDetId neighbor(HcalForward, ieta,iphi,1);
00121 HFRecHitCollection::const_iterator neigh=rec.find(neighbor);
00122 if (neigh!=rec.end())
00123 EL=neigh->energy();
00124
00125 if (EL>=energy)
00126 return;
00127 }
00128
00129
00130 double S9S1=0;
00131 int testphi=-99;
00132
00133
00134 for (int d=1;d<=2;++d)
00135 {
00136 for (int i=ieta-1;i<=ieta+1;++i)
00137 {
00138 testphi=iphi;
00139
00140
00141 if (abs(ieta)==39 && abs(i)>39 && testphi%4==1)
00142 testphi-=2;
00143 while (testphi<0) testphi+=72;
00144 if (i==ieta)
00145 if (d==depth || isS8S1_==true) continue;
00146
00147
00148 HcalDetId neighbor(HcalForward, i,testphi,d);
00149 HFRecHitCollection::const_iterator neigh=rec.find(neighbor);
00150
00151 if (neigh!=rec.end())
00152 {
00153 const uint32_t chanstat = myqual->getValues(neighbor)->getValue();
00154 int SeverityLevel=mySeverity->getSeverityLevel(neighbor, neigh->flags(),
00155 chanstat);
00156 if (SeverityLevel<=HcalAcceptSeverityLevel_)
00157 S9S1+=neigh->energy();
00158 }
00159 }
00160 }
00161
00162
00163
00164 int phiseg=2;
00165 if (abs(ieta)>39) phiseg=4;
00166 for (int d=1;d<=2;++d)
00167 {
00168 for (int i=iphi-phiseg;i<=iphi+phiseg;i+=phiseg)
00169 {
00170 if (i==iphi) continue;
00171 testphi=i;
00172
00173 while (testphi<0) testphi+=72;
00174 while (testphi>72) testphi-=72;
00175
00176 HcalDetId neighbor(HcalForward, ieta,testphi,d);
00177 HFRecHitCollection::const_iterator neigh=rec.find(neighbor);
00178 if (neigh!=rec.end())
00179 {
00180 const uint32_t chanstat = myqual->getValues(neighbor)->getValue();
00181 int SeverityLevel=mySeverity->getSeverityLevel(neighbor, neigh->flags(),
00182 chanstat);
00183 if (SeverityLevel<=HcalAcceptSeverityLevel_)
00184 S9S1+=neigh->energy();
00185 }
00186 }
00187 }
00188
00189 if (abs(ieta)==40)
00190 {
00191 for (int d=1;d<=2;++d)
00192 {
00193 HcalDetId neighbor(HcalForward, 39*abs(ieta)/ieta,(iphi+2)%72,d);
00194 HFRecHitCollection::const_iterator neigh=rec.find(neighbor);
00195 if (neigh!=rec.end())
00196 {
00197 const uint32_t chanstat = myqual->getValues(neighbor)->getValue();
00198 int SeverityLevel=mySeverity->getSeverityLevel(neighbor, neigh->flags(),
00199 chanstat);
00200 if (SeverityLevel<=HcalAcceptSeverityLevel_)
00201 S9S1+=neigh->energy();
00202 }
00203
00204 }
00205 }
00206
00207
00208 S9S1/=energy;
00209
00210
00211 double slope=0;
00212 if (depth==1) slope = LongSlopes[abs(ieta)-29];
00213 else if (depth==2) slope=ShortSlopes[abs(ieta)-29];
00214 double intercept = 0;
00215 if (depth==1) intercept = LongEnergyThreshold[abs(ieta)-29];
00216 else if (depth==2) intercept = ShortEnergyThreshold[abs(ieta)-29];
00217
00218
00219 double S9S1cut = 0;
00220
00221 if (intercept>0 && energy>0)
00222 S9S1cut=-1.*slope*log(intercept) + slope*log(energy);
00223 if (S9S1<S9S1cut)
00224 {
00225
00226 if (isS8S1_==true)
00227 hf.setFlagField(1,HcalCaloFlagLabels::HFS8S1Ratio);
00228
00229 hf.setFlagField(1,HcalCaloFlagLabels::HFLongShort);
00230 }
00231 return;
00232 }
00233
00234
00235
00236 double HcalHF_S9S1algorithm::CalcSlope(int abs_ieta, std::vector<double> params)
00237 {
00238
00239
00240
00241
00242
00243
00244 double threshold=0;
00245 for (std::vector<double>::size_type i=0;i<params.size();++i)
00246 {
00247 threshold+=params[i]*pow(static_cast<double>(abs_ieta), (int)i);
00248 }
00249 return threshold;
00250 }
00251
00252
00253
00254
00255 double HcalHF_S9S1algorithm::CalcEnergyThreshold(double abs_energy,std::vector<double> params)
00256 {
00257
00258
00259
00260
00261
00262 double threshold=0;
00263 for (std::vector<double>::size_type i=0;i<params.size();++i)
00264 {
00265 threshold+=params[i]*pow(abs_energy, (int)i);
00266 }
00267 return threshold;
00268 }
00269