#include <IsolatorByNominalEfficiency.h>
Classes | |
class | ConeSizes |
Public Types | |
typedef MuIsoBaseIsolator::DepositContainer | DepositContainer |
Public Member Functions | |
Cuts | cuts (float nominalEfficiency) const |
IsolatorByNominalEfficiency (const std::string &thrFile, const std::vector< std::string > &ceff, const std::vector< double > &weights, const std::vector< double > &thresh) | |
IsolatorByNominalEfficiency (const std::string &thrFile, const std::vector< std::string > &ceff, const std::vector< double > &weights) | |
Constructor. | |
virtual Result | result (DepositContainer deposits) const |
Compute the deposit within the cone and return the isolation result. | |
virtual | ~IsolatorByNominalEfficiency () |
Private Types | |
typedef std::multimap< float, int > | mapNomEff_Cone |
Private Member Functions | |
int | bestConeForEfficiencyIndex (float eff_thr) const |
mapNomEff_Cone | cones (const std::vector< std::string > &names) |
std::string | findPath (const std::string &fileName) |
virtual ResultType | resultType () const |
virtual double | weightedSum (const DepositContainer &deposits, float dRcone) const |
Private Attributes | |
mapNomEff_Cone | coneForEfficiency |
ConeSizes | theConesInfo |
std::vector< double > | theDepThresholds |
std::vector< double > | theWeights |
NominalEfficiencyThresholds * | thresholds |
Definition at line 21 of file IsolatorByNominalEfficiency.h.
typedef MuIsoBaseIsolator::DepositContainer muonisolation::IsolatorByNominalEfficiency::DepositContainer |
Reimplemented from muonisolation::MuIsoBaseIsolator.
Definition at line 23 of file IsolatorByNominalEfficiency.h.
typedef std::multimap<float,int> muonisolation::IsolatorByNominalEfficiency::mapNomEff_Cone [private] |
Definition at line 60 of file IsolatorByNominalEfficiency.h.
muonisolation::IsolatorByNominalEfficiency::IsolatorByNominalEfficiency | ( | const std::string & | thrFile, |
const std::vector< std::string > & | ceff, | ||
const std::vector< double > & | weights | ||
) |
Constructor.
muonisolation::IsolatorByNominalEfficiency::IsolatorByNominalEfficiency | ( | const std::string & | thrFile, |
const std::vector< std::string > & | ceff, | ||
const std::vector< double > & | weights, | ||
const std::vector< double > & | thresh | ||
) |
IsolatorByNominalEfficiency::~IsolatorByNominalEfficiency | ( | ) | [virtual] |
Definition at line 36 of file IsolatorByNominalEfficiency.cc.
References thresholds.
{ delete thresholds; }
int IsolatorByNominalEfficiency::bestConeForEfficiencyIndex | ( | float | eff_thr | ) | const [private] |
Definition at line 105 of file IsolatorByNominalEfficiency.cc.
References coneForEfficiency.
Referenced by result().
{ //FIXME use upper_bound int best_cone; if (coneForEfficiency.size() != 0) { best_cone = (--(coneForEfficiency.end()))->second; } else return 0; mapNomEff_Cone::const_reverse_iterator it; for (it = coneForEfficiency.rbegin(); it != coneForEfficiency.rend(); it++) { if (eff_thr <= (*it).first) best_cone = (*it).second; } return best_cone; }
IsolatorByNominalEfficiency::mapNomEff_Cone IsolatorByNominalEfficiency::cones | ( | const std::vector< std::string > & | names | ) | [private] |
Definition at line 42 of file IsolatorByNominalEfficiency.cc.
References result().
{ mapNomEff_Cone result; for (vector<string>::const_iterator is = usrVec.begin(); is != usrVec.end(); is++) { char * evp = 0; int cone = strtol( (*is).c_str(), &evp, 10); float effic = strtod(evp+1, &evp); result.insert(make_pair(effic,cone)); } return result; }
Cuts IsolatorByNominalEfficiency::cuts | ( | float | nominalEfficiency | ) | const |
Definition at line 132 of file BdecayFilter.cc.
References abs, gather_cfg::cout, eta(), i, j, and L1TEmulatorMonitor_cff::p.
Referenced by L3NominalEfficiencyConfigurator::cuts().
{ cout << "start cuts" << endl; HepMC::GenVertex* myVertex = jpsi->end_vertex(); int numChildren = myVertex->particles_out_size(); int numDecProd = cut.decayProduct.size(); std::vector<HepMC::GenParticle*> psiChild; // for(std::set<GenParticle*>::const_iterator p = myVertex->particles_out_const_begin(); for(GenVertex::particles_out_const_iterator p = myVertex->particles_out_const_begin(); p != myVertex->particles_out_const_end(); p++) psiChild.push_back((*p)); if (numChildren!=numDecProd) return false; cout << psiChild[0]->pdg_id()<<" "<<psiChild[1]->pdg_id()<<endl; for (int i=0; i<numChildren; ++i) { bool goodPart = false; for (int j=0; j < numChildren; ++j){ if (abs(psiChild[i]->pdg_id()) == abs(cut.decayProduct[j])) goodPart = true; } cout << psiChild[i]->momentum().perp() << endl; if ( !goodPart || (!etaInRange(psiChild[i]->momentum().eta(), cut.etaMin, cut.etaMax)) || (psiChild[i]->momentum().perp() < cut.ptMin) ) return false; } cout << "cuts true" << endl; return true; }
string IsolatorByNominalEfficiency::findPath | ( | const std::string & | fileName | ) | [private] |
Definition at line 54 of file IsolatorByNominalEfficiency.cc.
References f, and edm::FileInPath::fullPath().
{ // FIXME edm::FileInPath f(fileName); return f.fullPath(); }
MuIsoBaseIsolator::Result IsolatorByNominalEfficiency::result | ( | DepositContainer | deposits | ) | const [virtual] |
Compute the deposit within the cone and return the isolation result.
Implements muonisolation::MuIsoBaseIsolator.
Definition at line 62 of file IsolatorByNominalEfficiency.cc.
References bestConeForEfficiencyIndex(), gather_cfg::cout, tests::location, resultType(), muonisolation::IsolatorByNominalEfficiency::ConeSizes::size(), theConesInfo, thresholds, muonisolation::NominalEfficiencyThresholds::thresholdValueForEfficiency(), muonisolation::MuIsoBaseIsolator::Result::valFloat, and weightedSum().
Referenced by cones().
{ if (deposits.size()==0) { cout << "IsolatorByNominalEfficiency: no deposit" << endl; return Result(resultType()); //FIXME } // To determine the threshold, the direction of the cone of the first // set of deposits is used. // For algorithms where different cone axis definitions are used // for different types deposits (eg. HCAL and ECAL deposits for // calorimeter isolation), the first one is used to determine the threshold // value! float theEta = deposits.back().dep->eta(); // Try descending efficiency values to find the point where the candidate // becomes non isolated float nominalEfficiency = 1.; const float deltaeff=0.005; const float mineff=deltaeff; for (float eff=.995; eff>mineff; eff-=deltaeff) { int cone = bestConeForEfficiencyIndex(eff); float coneSize = theConesInfo.size(cone); NominalEfficiencyThresholds::ThresholdLocation location = {theEta,cone}; float thres = thresholds->thresholdValueForEfficiency(location, eff); float sumDep = weightedSum(deposits,coneSize); // cout << " Eff=" << eff // << " eta=" << theEta // << " cone=" << cone // << " dR=" << coneSize // << " thres=" << thres // << " deposit=" << sumDep // << " isolated=" << (sumDep < thres) // << endl; if (sumDep > thres) break; nominalEfficiency = eff; } Result res(resultType()); res.valFloat = nominalEfficiency; return res; }
virtual ResultType muonisolation::IsolatorByNominalEfficiency::resultType | ( | ) | const [inline, private, virtual] |
Implements muonisolation::MuIsoBaseIsolator.
Definition at line 65 of file IsolatorByNominalEfficiency.h.
References muonisolation::MuIsoBaseIsolator::ISOL_FLOAT_TYPE.
Referenced by result().
{ return ISOL_FLOAT_TYPE;}
double IsolatorByNominalEfficiency::weightedSum | ( | const DepositContainer & | deposits, |
float | dRcone | ||
) | const [private, virtual] |
Definition at line 123 of file IsolatorByNominalEfficiency.cc.
References theDepThresholds, and theWeights.
Referenced by result().
{ double sumDep=0; assert(deposits.size()==theWeights.size()); vector<double>::const_iterator w = theWeights.begin(); vector<double>::const_iterator dThresh = theDepThresholds.begin(); for (DepositContainer::const_iterator dep = deposits.begin(); dep != deposits.end(); dep++) { if (dep->vetos != 0){ sumDep += dep->dep->depositAndCountWithin(dRcone, *dep->vetos, *dThresh).first * (*w); } else { sumDep += dep->dep->depositAndCountWithin(dRcone, Vetos(), *dThresh).first * (*w); } if (sumDep <0.) sumDep = 0.; w++; dThresh++; } return sumDep; }
Definition at line 68 of file IsolatorByNominalEfficiency.h.
Referenced by bestConeForEfficiencyIndex().
Definition at line 72 of file IsolatorByNominalEfficiency.h.
Referenced by result().
std::vector<double> muonisolation::IsolatorByNominalEfficiency::theDepThresholds [private] |
Definition at line 71 of file IsolatorByNominalEfficiency.h.
Referenced by weightedSum().
std::vector<double> muonisolation::IsolatorByNominalEfficiency::theWeights [private] |
Definition at line 70 of file IsolatorByNominalEfficiency.h.
Referenced by weightedSum().
Definition at line 69 of file IsolatorByNominalEfficiency.h.
Referenced by result(), and ~IsolatorByNominalEfficiency().