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/data/refman/pasoursint/CMSSW_5_3_1/src/FastSimulation/ForwardDetectors/plugins/CastorFastClusterProducer.cc

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00001 // -*- C++ -*-
00002 //
00003 // Package:    CastorFastClusterProducer
00004 // Class:      CastorFastClusterProducer
00005 // 
00013 //
00014 // Original Author:  Hans Van Haevermaet
00015 //         Created:  Thu Mar 13 12:00:56 CET 2008
00016 // $Id: CastorFastClusterProducer.cc,v 1.2 2011/03/04 11:00:55 hvanhaev Exp $
00017 //
00018 //
00019 
00020 
00021 // system include files
00022 #include <memory>
00023 #include <vector>
00024 #include <iostream>
00025 #include <sstream>
00026 #include <TMath.h>
00027 #include <TRandom3.h>
00028 #include <TF1.h>
00029 
00030 // user include files
00031 #include "FWCore/Framework/interface/Frameworkfwd.h"
00032 #include "FWCore/Framework/interface/EDProducer.h"
00033 
00034 #include "FWCore/Framework/interface/Event.h"
00035 #include "FWCore/Framework/interface/MakerMacros.h"
00036 
00037 #include "FWCore/ParameterSet/interface/ParameterSet.h"
00038 
00039 #include "DataFormats/Math/interface/Point3D.h"
00040 
00041 // Castorobject includes
00042 #include "DataFormats/CastorReco/interface/CastorCluster.h"
00043 #include "DataFormats/HcalRecHit/interface/CastorRecHit.h"
00044 #include "DataFormats/HcalDetId/interface/HcalCastorDetId.h"
00045 
00046 // genCandidate particle includes
00047 #include "DataFormats/Candidate/interface/Candidate.h"
00048 #include "DataFormats/HepMCCandidate/interface/GenParticle.h"
00049 
00050 #include "FastSimulation/ForwardDetectors/plugins/CastorFastClusterProducer.h"
00051 
00052 
00053 //
00054 // constructors and destructor
00055 //
00056 CastorFastClusterProducer::CastorFastClusterProducer(const edm::ParameterSet& iConfig) 
00057 {
00058    //register your products
00059    produces<CastorClusterCollection>();
00060    
00061    //now do what ever other initialization is needed
00062 
00063 }
00064 
00065 
00066 CastorFastClusterProducer::~CastorFastClusterProducer()
00067 {
00068  
00069    // do anything here that needs to be done at desctruction time
00070    // (e.g. close files, deallocate resources etc.)
00071 
00072 }
00073 
00074 
00075 //
00076 // member functions
00077 //
00078 
00079 // ------------ method called to produce the data  ------------
00080 void
00081 CastorFastClusterProducer::produce(edm::Event& iEvent, const edm::EventSetup& iSetup)
00082 {
00083    using namespace edm;
00084    using namespace reco;
00085    using namespace std;
00086    using namespace TMath;
00087    
00088    //
00089    // Make CastorCluster objects
00090    //
00091    
00092    //cout << "entering event" << endl;
00093    
00094    Handle<GenParticleCollection> genParticles;
00095    iEvent.getByLabel("genParticles", genParticles);
00096    
00097    // make pointer to towers that will be made
00098    auto_ptr<CastorClusterCollection> CastorClusters (new CastorClusterCollection);
00099    
00100    /*
00101    // declare castor array
00102    double castorplus [4][16]; // (0,x): Energies - (1,x): emEnergies - (2,x): hadEnergies - (3,x): phi position - eta = 5.9
00103    double castormin [4][16];  // (0,x): Energies - (1,x): emEnergies - (2,x): hadEnergies - (3,x): phi position - eta = -5.9
00104    // set phi values of array sectors and everything else to zero
00105    for (int j = 0; j < 16; j++) {
00106         castorplus[3][j] = -2.94524 + j*0.3927;
00107         castormin[3][j] = -2.94524 + j*0.3927;
00108         castorplus[0][j] = 0.;
00109         castormin[0][j] = 0.;
00110         castorplus[1][j] = 0.;
00111         castormin[1][j] = 0.;
00112         castorplus[2][j] = 0.;
00113         castormin[2][j] = 0.; 
00114         //castorplus[4][j] = 0.;
00115         //castormin[4][j] = 0.;
00116    }
00117    
00118    // declare properties vectors
00119    vector<double> depthplus[16];
00120    vector<double> depthmin[16];
00121    vector<double> fhotplus [16];
00122    vector<double> fhotmin [16];
00123    vector<double> energyplus [16];
00124    vector<double> energymin [16];
00125    
00126    for (int i=0;i<16;i++) {
00127         depthplus[i].clear();
00128         depthmin[i].clear();
00129         fhotplus[i].clear();
00130         fhotmin[i].clear();
00131         energyplus[i].clear();
00132         energymin[i].clear();
00133    }
00134    */
00135    
00136    //cout << "declared everything" << endl;
00137    
00138    // start particle loop
00139    for (size_t i = 0; i < genParticles->size(); ++i) {
00140         const Candidate & p = (*genParticles)[i];
00141         
00142         // select particles in castor
00143         if ( fabs(p.eta()) > 5.2 && fabs(p.eta()) < 6.6) {
00144         
00145             //cout << "found particle in castor, start calculating" << endl;
00146             
00147             // declare energies
00148             double gaus_E = -1.; 
00149             double emEnergy = 0.;
00150             double hadEnergy = 0.;
00151             //double fhot = 0.;
00152             //double depth = 0.;
00153             
00154             // add energies - em: if particle is e- or gamma
00155             if (p.pdgId() == 11 || p.pdgId() == 22) {
00156                 
00157                 while ( gaus_E < 0.) {
00158                 // apply energy smearing with gaussian random generator
00159                 TRandom3 r(0);
00160                 // use sigma/E parametrization for the EM sections of CASTOR TB 2007 results
00161                 double sigma = p.energy()*(sqrt(pow(0.044,2) + pow(0.513/sqrt(p.energy()),2)));
00162                 gaus_E = r.Gaus(p.energy(),sigma);
00163                 }
00164             
00165                 // calculate electromagnetic electron/photon energy leakage
00166                 double tmax;
00167                 double a;
00168                 double cte;
00169                 if ( p.pdgId() == 11) { cte = -0.5; } else { cte = 0.5; }
00170                 tmax = 1.0*(log(gaus_E/0.0015)+cte);
00171                 a = tmax*0.5 + 1;
00172                 double leakage;
00173                 double x = 0.5*19.38;
00174                 leakage = gaus_E - gaus_E*Gamma(a,x);
00175                 
00176                 // add emEnergy
00177                 emEnergy = gaus_E - leakage;
00178                 // add hadEnergy leakage
00179                 hadEnergy = leakage;
00180                 
00181                 // make cluster
00182                 ClusterPoint pt1;
00183                 if (p.eta() > 0.) {ClusterPoint temp(88.5,5.9,p.phi()); pt1 = temp;}
00184                 if (p.eta() < 0.) {ClusterPoint temp(88.5,-5.9,p.phi()); pt1 = temp;}
00185                 Point pt2(pt1);
00186                 CastorTowerRefVector refvector;
00187                 CastorClusters->push_back(reco::CastorCluster(gaus_E,pt2,emEnergy,hadEnergy,emEnergy/gaus_E,0.,0.,0.,0.,refvector));
00188                 
00189             } else {
00190             
00191                 while (gaus_E < 0.) {
00192                 // apply energy smearing with gaussian random generator
00193                 TRandom3 r(0);
00194                 // use sigma/E parametrization for the HAD sections of CASTOR TB 2007 results
00195                 double sigma = p.energy()*(sqrt(pow(0.121,2) + pow(1.684/sqrt(p.energy()),2)));
00196                 gaus_E = r.Gaus(p.energy(),sigma);
00197                 }
00198                 
00199                 // add hadEnergy
00200                 hadEnergy = gaus_E;
00201                 
00202                 // make cluster
00203                 ClusterPoint pt1;
00204                 if (p.eta() > 0.) {ClusterPoint temp(88.5,5.9,p.phi()); pt1 = temp;}
00205                 if (p.eta() < 0.) {ClusterPoint temp(88.5,-5.9,p.phi()); pt1 = temp;}
00206                 Point pt2(pt1);
00207                 CastorTowerRefVector refvector;
00208                 CastorClusters->push_back(reco::CastorCluster(gaus_E,pt2,0.,hadEnergy,0.,0.,0.,0.,0.,refvector));
00209             }
00210             
00211             /*
00212             // make tower
00213             
00214             // set sector
00215             int sector = -1;
00216             for (int j = 0; j < 16; j++) {
00217                 double a = -M_PI + j*0.3927;
00218                 double b = -M_PI + (j+1)*0.3927;
00219                 if ( (p.phi() > a) && (p.phi() < b)) {  
00220                    sector = j;
00221                 }
00222             }
00223             
00224             // set eta
00225             if (p.eta() > 0) { 
00226                 castorplus[0][sector] = castorplus[0][sector] + gaus_E;
00227                 castorplus[1][sector] = castorplus[1][sector] + emEnergy;
00228                 castorplus[2][sector] = castorplus[2][sector] + hadEnergy;
00229                 
00230                 depthplus[sector].push_back(depth);
00231                 fhotplus[sector].push_back(fhot);
00232                 energyplus[sector].push_back(gaus_E);
00233                 //cout << "filled vectors" << endl;
00234                 //cout << "energyplus size = " << energyplus[sector].size() << endl;
00235                 //cout << "depthplus size = " << depthplus[sector].size() << endl;
00236                 //cout << "fhotplus size = " << fhotplus[sector].size() << endl;
00237                 
00238             } else { 
00239                 castormin[0][sector] = castormin[0][sector] + gaus_E;
00240                 castormin[1][sector] = castormin[1][sector] + emEnergy;
00241                 castormin[2][sector] = castormin[2][sector] + hadEnergy;
00242                 
00243                 
00244                 depthmin[sector].push_back(depth);
00245                 fhotmin[sector].push_back(fhot);
00246                 energymin[sector].push_back(gaus_E);
00247                 //cout << "filled vectors" << endl;
00248                 
00249             }
00250             */
00251             
00252         }
00253         
00254    }
00255    
00256    /*
00257    // substract pedestals/noise
00258    for (int j = 0; j < 16; j++) {
00259         double hadnoise = 0.;
00260         for (int i=0;i<12;i++) {
00261                 hadnoise = hadnoise + make_noise();
00262         }
00263         castorplus[0][j] = castorplus[0][j] - hadnoise - make_noise() - make_noise();
00264         castormin[0][j] = castormin[0][j] - hadnoise - make_noise() - make_noise();
00265         castorplus[1][j] = castorplus[1][j] - make_noise() - make_noise();
00266         castormin[1][j] = castormin[1][j] - make_noise() - make_noise();
00267         castorplus[2][j] = castorplus[2][j] - hadnoise;
00268         castormin[2][j] = castormin[2][j] - hadnoise; 
00269         
00270         // set possible negative values to zero
00271         if (castorplus[0][j] < 0.) castorplus[0][j] = 0.;
00272         if (castormin[0][j] < 0.) castormin[0][j] = 0.;
00273         if (castorplus[1][j] < 0.) castorplus[1][j] = 0.;
00274         if (castormin[1][j] < 0.) castormin[1][j] = 0.;
00275         if (castorplus[2][j] < 0.) castorplus[2][j] = 0.;
00276         if (castormin[2][j] < 0.) castormin[2][j] = 0.;
00277    }
00278    */
00279    
00280    /*
00281    // store towers from castor arrays
00282    // eta = 5.9
00283    for (int j=0;j<16;j++) {
00284         if (castorplus[0][j] > 0.) {
00285             
00286             double fem = 0.;
00287             fem = castorplus[1][j]/castorplus[0][j]; 
00288             ClusterPoint pt1(88.5,5.9,castorplus[3][j]);
00289             Point pt2(pt1); 
00290             
00291             // parametrize depth and fhot from full sim
00292             // get fit parameters from energy
00293             // get random number according to distribution with fit parameters
00294             double depth_mean = 0.;
00295             double fhot_mean = 0.;
00296             double sum_energy = 0.;
00297             
00298             //cout << "energyplus size = " << energyplus[j].size()<< endl;
00299             for (size_t p = 0; p<energyplus[j].size();p++) {
00300                 depth_mean = depth_mean + depthplus[j][p]*energyplus[j][p];
00301                 fhot_mean = fhot_mean + fhotplus[j][p]*energyplus[j][p];
00302                 sum_energy = sum_energy + energyplus[j][p];
00303             }
00304             depth_mean = depth_mean/sum_energy;
00305             fhot_mean = fhot_mean/sum_energy;
00306             cout << "computed depth/fhot" << endl;
00307             
00308             
00309             edm::RefVector<edm::SortedCollection<CastorRecHit> > refvector;
00310             CastorClusters->push_back(reco::CastorCluster(castorplus[0][j],pt2,castorplus[1][j],castorplus[2][j],fem,depth_mean,fhot_mean,refvector));  
00311         }
00312    }
00313    // eta = -5.9
00314    for (int j=0;j<16;j++) {
00315         if (castormin[0][j] > 0.) {
00316             double fem = 0.;
00317             fem = castormin[1][j]/castormin[0][j]; 
00318             ClusterPoint pt1(88.5,-5.9,castormin[3][j]);
00319             Point pt2(pt1); 
00320             
00321             // parametrize depth and fhot from full sim
00322             // get fit parameters from energy
00323             // get random number according to distribution with fit parameters
00324             double depth_mean = 0.;
00325             double fhot_mean = 0.;
00326             double sum_energy = 0.;
00327             
00328             
00329             for (size_t p = 0; p<energymin[j].size();p++) {
00330                 depth_mean = depth_mean + depthmin[j][p]*energymin[j][p];
00331                 fhot_mean = fhot_mean + fhotmin[j][p]*energymin[j][p];
00332                 sum_energy = sum_energy + energymin[j][p];
00333             }
00334             depth_mean = depth_mean/sum_energy;
00335             fhot_mean = fhot_mean/sum_energy;
00336             
00337             
00338             edm::RefVector<edm::SortedCollection<CastorRecHit> > refvector;
00339             CastorClusters->push_back(reco::CastorCluster(castormin[0][j],pt2,castormin[1][j],castormin[2][j],fem,depth_mean,fhot_mean,refvector));     
00340         }
00341    }
00342    */
00343         
00344    iEvent.put(CastorClusters); 
00345    
00346 }
00347 
00348 double CastorFastClusterProducer::make_noise() {
00349         double result = -1.;
00350         TRandom3 r2(0);
00351         double mu_noise = 0.053; // GeV (from 1.214 ADC) per channel
00352         double sigma_noise = 0.027; // GeV (from 0.6168 ADC) per channel
00353         
00354         while (result < 0.) {
00355                 result = r2.Gaus(mu_noise,sigma_noise);
00356         }
00357         
00358         return result;
00359 }
00360 
00361 
00362 // ------------ method called once each job just before starting event loop  ------------
00363 void 
00364 CastorFastClusterProducer::beginRun(edm::Run& run, edm::EventSetup const& es)
00365 {
00366 }
00367 
00368 // ------------ method called once each job just after ending the event loop  ------------
00369 void 
00370 CastorFastClusterProducer::endRun() {
00371 }
00372 
00373 //define this as a plug-in
00374 DEFINE_FWK_MODULE(CastorFastClusterProducer);