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00021 #include <memory>
00022
00023
00024 #include "FWCore/Framework/interface/Frameworkfwd.h"
00025 #include "FWCore/Framework/interface/EDProducer.h"
00026
00027 #include "FWCore/Framework/interface/Event.h"
00028 #include "FWCore/Framework/interface/MakerMacros.h"
00029
00030 #include "FWCore/ParameterSet/interface/ParameterSet.h"
00031
00032 #include "DataFormats/MuonReco/interface/Muon.h"
00033 #include "DataFormats/MuonReco/interface/MuonFwd.h"
00034 #include "DataFormats/MuonReco/interface/MuonTimeExtra.h"
00035 #include "DataFormats/MuonReco/interface/MuonTimeExtraMap.h"
00036
00037 #include "RecoMuon/MuonIdentification/interface/MuonTimingFiller.h"
00038 #include "RecoMuon/MuonIdentification/interface/TimeMeasurementSequence.h"
00039 #include "DataFormats/EcalDetId/interface/EcalSubdetector.h"
00040
00041
00042
00043
00044 MuonTimingFiller::MuonTimingFiller(const edm::ParameterSet& iConfig)
00045 {
00046
00047 edm::ParameterSet dtTimingParameters = iConfig.getParameter<edm::ParameterSet>("DTTimingParameters");
00048 theDTTimingExtractor_ = new DTTimingExtractor(dtTimingParameters);
00049
00050
00051 edm::ParameterSet cscTimingParameters = iConfig.getParameter<edm::ParameterSet>("CSCTimingParameters");
00052 theCSCTimingExtractor_ = new CSCTimingExtractor(cscTimingParameters);
00053
00054 errorEB_ = iConfig.getParameter<double>("ErrorEB");
00055 errorEE_ = iConfig.getParameter<double>("ErrorEE");
00056 ecalEcut_ = iConfig.getParameter<double>("EcalEnergyCut");
00057
00058 useDT_ = iConfig.getParameter<bool>("UseDT");
00059 useCSC_ = iConfig.getParameter<bool>("UseCSC");
00060 useECAL_ = iConfig.getParameter<bool>("UseECAL");
00061
00062 }
00063
00064
00065 MuonTimingFiller::~MuonTimingFiller()
00066 {
00067 if (theDTTimingExtractor_) delete theDTTimingExtractor_;
00068 if (theCSCTimingExtractor_) delete theCSCTimingExtractor_;
00069 }
00070
00071
00072
00073
00074
00075
00076 void
00077 MuonTimingFiller::fillTiming( const reco::Muon& muon, reco::MuonTimeExtra& dtTime, reco::MuonTimeExtra& cscTime, reco::MuonTimeExtra& combinedTime, edm::Event& iEvent, const edm::EventSetup& iSetup )
00078 {
00079 TimeMeasurementSequence dtTmSeq,cscTmSeq;
00080
00081 if ( !(muon.combinedMuon().isNull()) ) {
00082 theDTTimingExtractor_->fillTiming(dtTmSeq, muon.combinedMuon(), iEvent, iSetup);
00083 theCSCTimingExtractor_->fillTiming(cscTmSeq, muon.combinedMuon(), iEvent, iSetup);
00084 } else
00085 if ( !(muon.standAloneMuon().isNull()) ) {
00086 theDTTimingExtractor_->fillTiming(dtTmSeq, muon.standAloneMuon(), iEvent, iSetup);
00087 theCSCTimingExtractor_->fillTiming(cscTmSeq, muon.standAloneMuon(), iEvent, iSetup);
00088 }
00089
00090
00091 fillTimeFromMeasurements(dtTmSeq, dtTime);
00092
00093
00094 fillTimeFromMeasurements(cscTmSeq, cscTime);
00095
00096
00097 TimeMeasurementSequence combinedTmSeq;
00098 combineTMSequences(muon,dtTmSeq,cscTmSeq,combinedTmSeq);
00099
00100 if (useECAL_) addEcalTime(muon,combinedTmSeq);
00101
00102
00103 fillTimeFromMeasurements(combinedTmSeq, combinedTime);
00104
00105 LogTrace("MuonTime") << "Global 1/beta: " << combinedTime.inverseBeta() << " +/- " << combinedTime.inverseBetaErr()<<std::endl;
00106 LogTrace("MuonTime") << " Free 1/beta: " << combinedTime.freeInverseBeta() << " +/- " << combinedTime.freeInverseBetaErr()<<std::endl;
00107 LogTrace("MuonTime") << " Vertex time (in-out): " << combinedTime.timeAtIpInOut() << " +/- " << combinedTime.timeAtIpInOutErr()
00108 << " # of points: " << combinedTime.nDof() <<std::endl;
00109 LogTrace("MuonTime") << " Vertex time (out-in): " << combinedTime.timeAtIpOutIn() << " +/- " << combinedTime.timeAtIpOutInErr()<<std::endl;
00110 LogTrace("MuonTime") << " direction: " << combinedTime.direction() << std::endl;
00111
00112 }
00113
00114
00115 void
00116 MuonTimingFiller::fillTimeFromMeasurements( const TimeMeasurementSequence& tmSeq, reco::MuonTimeExtra &muTime ) {
00117
00118 std::vector <double> x,y;
00119 double invbeta=0, invbetaerr=0;
00120 double vertexTime=0, vertexTimeErr=0, vertexTimeR=0, vertexTimeRErr=0;
00121 double freeBeta, freeBetaErr, freeTime, freeTimeErr;
00122
00123 if (tmSeq.dstnc.size()<=1) return;
00124
00125 for (unsigned int i=0;i<tmSeq.dstnc.size();i++) {
00126 invbeta+=(1.+tmSeq.local_t0.at(i)/tmSeq.dstnc.at(i)*30.)*tmSeq.weightInvbeta.at(i)/tmSeq.totalWeightInvbeta;
00127 x.push_back(tmSeq.dstnc.at(i)/30.);
00128 y.push_back(tmSeq.local_t0.at(i)+tmSeq.dstnc.at(i)/30.);
00129 vertexTime+=tmSeq.local_t0.at(i)*tmSeq.weightVertex.at(i)/tmSeq.totalWeightVertex;
00130 vertexTimeR+=(tmSeq.local_t0.at(i)+2*tmSeq.dstnc.at(i)/30.)*tmSeq.weightVertex.at(i)/tmSeq.totalWeightVertex;
00131 }
00132
00133 double diff;
00134 for (unsigned int i=0;i<tmSeq.dstnc.size();i++) {
00135 diff=(1.+tmSeq.local_t0.at(i)/tmSeq.dstnc.at(i)*30.)-invbeta;
00136 invbetaerr+=diff*diff*tmSeq.weightInvbeta.at(i);
00137 diff=tmSeq.local_t0.at(i)-vertexTime;
00138 vertexTimeErr+=diff*diff*tmSeq.weightVertex.at(i);
00139 diff=tmSeq.local_t0.at(i)+2*tmSeq.dstnc.at(i)/30.-vertexTimeR;
00140 vertexTimeRErr+=diff*diff*tmSeq.weightVertex.at(i);
00141 }
00142
00143 double cf = 1./(tmSeq.dstnc.size()-1);
00144 invbetaerr=sqrt(invbetaerr/tmSeq.totalWeightInvbeta*cf);
00145 vertexTimeErr=sqrt(vertexTimeErr/tmSeq.totalWeightVertex*cf);
00146 vertexTimeRErr=sqrt(vertexTimeRErr/tmSeq.totalWeightVertex*cf);
00147
00148 muTime.setInverseBeta(invbeta);
00149 muTime.setInverseBetaErr(invbetaerr);
00150 muTime.setTimeAtIpInOut(vertexTime);
00151 muTime.setTimeAtIpInOutErr(vertexTimeErr);
00152 muTime.setTimeAtIpOutIn(vertexTimeR);
00153 muTime.setTimeAtIpOutInErr(vertexTimeRErr);
00154
00155 rawFit(freeBeta, freeBetaErr, freeTime, freeTimeErr, x, y);
00156
00157 muTime.setFreeInverseBeta(freeBeta);
00158 muTime.setFreeInverseBetaErr(freeBetaErr);
00159
00160 muTime.setNDof(tmSeq.dstnc.size());
00161 }
00162
00163 void
00164 MuonTimingFiller::combineTMSequences( const reco::Muon& muon,
00165 const TimeMeasurementSequence& dtSeq,
00166 const TimeMeasurementSequence& cscSeq,
00167 TimeMeasurementSequence &cmbSeq ) {
00168
00169 if (useDT_) for (unsigned int i=0;i<dtSeq.dstnc.size();i++) {
00170 cmbSeq.dstnc.push_back(dtSeq.dstnc.at(i));
00171 cmbSeq.local_t0.push_back(dtSeq.local_t0.at(i));
00172 cmbSeq.weightVertex.push_back(dtSeq.weightVertex.at(i));
00173 cmbSeq.weightInvbeta.push_back(dtSeq.weightInvbeta.at(i));
00174
00175 cmbSeq.totalWeightVertex+=dtSeq.weightVertex.at(i);
00176 cmbSeq.totalWeightInvbeta+=dtSeq.weightInvbeta.at(i);
00177 }
00178
00179 if (useCSC_) for (unsigned int i=0;i<cscSeq.dstnc.size();i++) {
00180 cmbSeq.dstnc.push_back(cscSeq.dstnc.at(i));
00181 cmbSeq.local_t0.push_back(cscSeq.local_t0.at(i));
00182 cmbSeq.weightVertex.push_back(cscSeq.weightVertex.at(i));
00183 cmbSeq.weightInvbeta.push_back(cscSeq.weightInvbeta.at(i));
00184
00185 cmbSeq.totalWeightVertex+=cscSeq.weightVertex.at(i);
00186 cmbSeq.totalWeightInvbeta+=cscSeq.weightInvbeta.at(i);
00187 }
00188 }
00189
00190
00191 void
00192 MuonTimingFiller::addEcalTime( const reco::Muon& muon,
00193 TimeMeasurementSequence &cmbSeq ) {
00194
00195 reco::MuonEnergy muonE;
00196 if (muon.isEnergyValid())
00197 muonE = muon.calEnergy();
00198
00199
00200
00201 if (muonE.emMax<ecalEcut_) return;
00202
00203
00204 double emErr;
00205 if (muonE.ecal_id.subdetId()==EcalBarrel) emErr= errorEB_/muonE.emMax; else
00206 emErr=errorEE_/muonE.emMax;
00207 double hitWeight = 1/(emErr*emErr);
00208 double hitDist=muonE.ecal_position.r();
00209
00210 cmbSeq.local_t0.push_back(muonE.ecal_time);
00211 cmbSeq.weightVertex.push_back(hitWeight);
00212 cmbSeq.weightInvbeta.push_back(hitDist*hitDist*hitWeight/(30.*30.));
00213
00214 cmbSeq.dstnc.push_back(hitDist);
00215
00216 cmbSeq.totalWeightVertex+=hitWeight;
00217 cmbSeq.totalWeightInvbeta+=hitDist*hitDist*hitWeight/(30.*30.);
00218
00219 }
00220
00221
00222
00223 void
00224 MuonTimingFiller::rawFit(double &a, double &da, double &b, double &db, const std::vector<double>& hitsx, const std::vector<double>& hitsy) {
00225
00226 double s=0,sx=0,sy=0,x,y;
00227 double sxx=0,sxy=0;
00228
00229 a=b=0;
00230 if (hitsx.size()==0) return;
00231 if (hitsx.size()==1) {
00232 b=hitsy[0];
00233 } else {
00234 for (unsigned int i = 0; i != hitsx.size(); i++) {
00235 x=hitsx[i];
00236 y=hitsy[i];
00237 sy += y;
00238 sxy+= x*y;
00239 s += 1.;
00240 sx += x;
00241 sxx += x*x;
00242 }
00243
00244 double d = s*sxx - sx*sx;
00245 b = (sxx*sy- sx*sxy)/ d;
00246 a = (s*sxy - sx*sy) / d;
00247 da = sqrt(sxx/d);
00248 db = sqrt(s/d);
00249 }
00250 }
00251