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/data/refman/pasoursint/CMSSW_4_1_8_patch9/src/SimGeneral/GFlash/src/GflashPiKShowerProfile.cc

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00001 #include "SimGeneral/GFlash/interface/GflashPiKShowerProfile.h"
00002 #include <CLHEP/Random/RandGaussQ.h>
00003 
00004 void GflashPiKShowerProfile::loadParameters()
00005 {
00006   double einc = theShowino->getEnergy();
00007   Gflash3Vector position = theShowino->getPositionAtShower();
00008   int showerType = theShowino->getShowerType();
00009 
00010   // energy scale
00011   double energyMeanHcal = 0.0;
00012   double energySigmaHcal = 0.0;
00013 
00014   if(showerType == 0 || showerType == 1 || showerType == 4 || showerType == 5) {
00015 
00016     double r1 = 0.0;
00017     double r2 = 0.0;
00018 
00019     //@@@ energy dependent energyRho based on tuning with testbeam data
00020     double energyRho =  fTanh(einc,Gflash::correl_hadem); 
00021 
00022     r1 = CLHEP::RandGaussQ::shoot();
00023 
00024     if(showerType == 0 || showerType == 1) {
00025       energyScale[Gflash::kESPM] = einc*(fTanh(einc,Gflash::emscale[0]) + fTanh(einc,Gflash::emcorr_pid[0])
00026         +(fTanh(einc,Gflash::emscale[2]) + fTanh(einc,Gflash::emscale[3])*depthScale(position.getRho(),151.,22.) )*r1);
00027 
00028       energyMeanHcal  = (fTanh(einc,Gflash::hadscale[0]) + 
00029                          fTanh(einc,Gflash::hadscale[1])*depthScale(position.getRho(),Gflash::RFrontCrystalEB,Gflash::LengthCrystalEB));
00030       energySigmaHcal = (fTanh(einc,Gflash::hadscale[2]) + 
00031                          fTanh(einc,Gflash::hadscale[3])*depthScale(position.getRho(),Gflash::RFrontCrystalEB,Gflash::LengthCrystalEB));
00032 
00033       r2 = CLHEP::RandGaussQ::shoot();
00034       energyScale[Gflash::kHB] = std::max(0.0, 
00035         einc*fTanh(einc,Gflash::hadcorr_pid[0]) +
00036         exp(energyMeanHcal+energySigmaHcal*(energyRho*r1 + sqrt(1.0- energyRho*energyRho)*r2 ))-0.05*einc);
00037     }
00038     else {
00039       energyScale[Gflash::kENCA] = einc*(fTanh(einc,Gflash::emscale[0]) + fTanh(einc,Gflash::emcorr_pid[1])
00040         +(fTanh(einc,Gflash::emscale[2]) + fTanh(einc,Gflash::emscale[3])*depthScale(std::fabs(position.getZ()),338.0,21.) )*r1);
00041 
00042       //@@@extend depthScale for HE
00043       energyMeanHcal  = (fTanh(einc,Gflash::hadscale[0]) + 
00044                          fTanh(einc,Gflash::hadscale[1])*depthScale(std::fabs(position.getZ()),Gflash::ZFrontCrystalEE,Gflash::LengthCrystalEE));
00045       energySigmaHcal = (fTanh(einc,Gflash::hadscale[2]) +
00046                          fTanh(einc,Gflash::hadscale[3])*depthScale(std::fabs(position.getZ()),Gflash::ZFrontCrystalEE,Gflash::LengthCrystalEE));
00047       r2 = CLHEP::RandGaussQ::shoot();
00048       energyScale[Gflash::kHE] = std::max(0.0,
00049         einc*fTanh(einc,Gflash::hadcorr_pid[1]) +
00050         exp(energyMeanHcal+energySigmaHcal*(energyRho*r1 + sqrt(1.0- energyRho*energyRho)*r2 ))-0.05*einc);
00051     }
00052   }
00053   else if(showerType == 2 || showerType == 6 || showerType == 3 || showerType == 7) { 
00054     //Hcal response for mip-like pions (mip)
00055     
00056     energyMeanHcal  = fTanh(einc,Gflash::hadscale[4]);
00057     energySigmaHcal = fTanh(einc,Gflash::hadscale[5]);
00058     double gap_corr = einc * fTanh(einc,Gflash::hadscale[6]);
00059 
00060     if(showerType == 2 || showerType == 3) {
00061       energyScale[Gflash::kHB] = std::max(0.0, einc*fTanh(einc,Gflash::mipcorr_pid[0]) +
00062                                  exp(energyMeanHcal+energySigmaHcal*CLHEP::RandGaussQ::shoot())-2.0);
00063       if(showerType == 2) {
00064         energyScale[Gflash::kHB] = std::max(0.0,energyScale[Gflash::kHB]
00065                                  - gap_corr*depthScale(position.getRho(),Gflash::Rmin[Gflash::kHB],28.));
00066       }
00067     }
00068     else if(showerType == 6 || showerType == 7 ) {
00069       energyScale[Gflash::kHE] = std::max(0.0, einc*fTanh(einc,Gflash::mipcorr_pid[1]) +
00070                                  exp(energyMeanHcal+energySigmaHcal*CLHEP::RandGaussQ::shoot())-2.0);
00071       if(showerType == 6) {
00072         energyScale[Gflash::kHE] = std::max(0.0,energyScale[Gflash::kHE]
00073                                  - gap_corr*depthScale(std::fabs(position.getZ()),Gflash::Zmin[Gflash::kHE],66.));
00074       }
00075     }
00076   }
00077 
00078   // parameters for the longitudinal profiles
00079   //@@@check longitudinal profiles of endcaps for possible variations
00080   double *rhoHcal = new double [2*Gflash::NPar];
00081   double *correlationVectorHcal = new double [Gflash::NPar*(Gflash::NPar+1)/2];
00082 
00083   //@@@until we have a separate parameterization for Endcap 
00084   bool isEndcap = false;
00085   if(showerType>3) {
00086     showerType -= 4;
00087     isEndcap = true;
00088   }
00089   //no separate parameterization before crystal
00090   if(showerType==0) showerType = 1; 
00091 
00092   //Hcal parameters are always needed regardless of showerType
00093   for(int i = 0 ; i < 2*Gflash::NPar ; i++ ) {
00094     rhoHcal[i] = fTanh(einc,Gflash::rho[i + showerType*2*Gflash::NPar]);
00095   }
00096 
00097   getFluctuationVector(rhoHcal,correlationVectorHcal);
00098 
00099   double normalZ[Gflash::NPar];
00100   for (int i = 0; i < Gflash::NPar ; i++) normalZ[i] = CLHEP::RandGaussQ::shoot();
00101   
00102   for(int i = 0 ; i < Gflash::NPar ; i++) {
00103     double correlationSum = 0.0;
00104     for(int j = 0 ; j < i+1 ; j++) {
00105       correlationSum += correlationVectorHcal[i*(i+1)/2+j]*normalZ[j];
00106     }
00107     longHcal[i] = fTanh(einc,Gflash::par[i+showerType*Gflash::NPar]) +
00108                   fTanh(einc,Gflash::par[i+(4+showerType)*Gflash::NPar])*correlationSum;
00109   }
00110 
00111   delete [] rhoHcal;
00112   delete [] correlationVectorHcal;
00113 
00114   // lateral parameters for Hcal
00115 
00116   for (int i = 0 ; i < Gflash::Nrpar ; i++) {
00117     lateralPar[Gflash::kHB][i] = fLnE1(einc,Gflash::rpar[i+showerType*Gflash::Nrpar]);
00118 
00119     //tuning for pure hadronic response: +10%
00120     if(showerType==3 && i == 0) lateralPar[Gflash::kHB][i] *= 1.1;
00121     lateralPar[Gflash::kHE][i] = lateralPar[Gflash::kHB][i];
00122   }
00123 
00124   //Ecal parameters are needed if and only if the shower starts inside the crystal
00125 
00126   if(showerType == 1) {
00127     //A depth dependent correction for the core term of R in Hcal is the linear in 
00128     //the shower start point while for the spread term is nearly constant
00129 
00130     if(!isEndcap) lateralPar[Gflash::kHB][0] -= 2.3562e-01*(position.getRho()-131.0); 
00131     else  lateralPar[Gflash::kHE][0] -= 2.3562e-01*(std::abs(position.getZ())-332.0);
00132 
00133     double *rhoEcal = new double [2*Gflash::NPar];
00134     double *correlationVectorEcal = new double [Gflash::NPar*(Gflash::NPar+1)/2];
00135     for(int i = 0 ; i < 2*Gflash::NPar ; i++ ) rhoEcal[i] = fTanh(einc,Gflash::rho[i]);
00136 
00137     getFluctuationVector(rhoEcal,correlationVectorEcal);
00138 
00139     for (int i = 0; i < Gflash::NPar ; i++) normalZ[i] = CLHEP::RandGaussQ::shoot();
00140     for(int i = 0 ; i < Gflash::NPar ; i++) {
00141       double correlationSum = 0.0;
00142       for(int j = 0 ; j < i+1 ; j++) {
00143         correlationSum += correlationVectorEcal[i*(i+1)/2+j]*normalZ[j];
00144       }
00145       longEcal[i] = fTanh(einc,Gflash::par[i]) +
00146         fTanh(einc,Gflash::par[i+4*Gflash::NPar])*correlationSum;
00147     }
00148 
00149     delete [] rhoEcal;
00150     delete [] correlationVectorEcal;
00151 
00152     // lateral parameters for Ecal
00153 
00154     for (int i = 0 ; i < Gflash::Nrpar ; i++) {
00155       lateralPar[Gflash::kESPM][i] = fLnE1(einc,Gflash::rpar[i]);
00156       lateralPar[Gflash::kENCA][i] = lateralPar[Gflash::kESPM][i];
00157     }
00158   }
00159 
00160 }