L1TowerCalibrator Class Reference

#include <L1TowerCalibrator.cc>

Inheritance diagram for L1TowerCalibrator:

Public Member Functions
	L1TowerCalibrator (const edm::ParameterSet &)
Public Member Functions inherited from edm::one::EDProducer<>
	EDProducer ()=default
	EDProducer (const EDProducer &)=delete
SerialTaskQueue *	globalLuminosityBlocksQueue () final
SerialTaskQueue *	globalRunsQueue () final
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginProcessBlocks () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndProcessBlocks () const final
bool	hasAbilityToProduceInEndRuns () const final
const EDProducer &	operator= (const EDProducer &)=delete
bool	wantsGlobalLuminosityBlocks () const final
bool	wantsGlobalRuns () const final
bool	wantsInputProcessBlocks () const final
bool	wantsProcessBlocks () const final
Public Member Functions inherited from edm::one::EDProducerBase
	EDProducerBase ()
ModuleDescription const &	moduleDescription () const
bool	wantsStreamLuminosityBlocks () const
bool	wantsStreamRuns () const
	~EDProducerBase () override
Public Member Functions inherited from edm::ProducerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
std::vector< edm::ProductResolverIndex > const &	indiciesForPutProducts (BranchType iBranchType) const
	ProducerBase ()
std::vector< edm::ProductResolverIndex > const &	putTokenIndexToProductResolverIndex () const
std::vector< bool > const &	recordProvenanceList () const
void	registerProducts (ProducerBase *, ProductRegistry *, ModuleDescription const &)
std::function< void(BranchDescription const &)>	registrationCallback () const
	used by the fwk to register list of products More...
void	resolvePutIndicies (BranchType iBranchType, ModuleToResolverIndicies const &iIndicies, std::string const &moduleLabel)
TypeLabelList const &	typeLabelList () const
	used by the fwk to register the list of products of this module More...
	~ProducerBase () noexcept(false) override
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...
	EDConsumerBase ()
	EDConsumerBase (EDConsumerBase const &)=delete
	EDConsumerBase (EDConsumerBase &&)=default
ESProxyIndex const *	esGetTokenIndices (edm::Transition iTrans) const
std::vector< ESProxyIndex > const &	esGetTokenIndicesVector (edm::Transition iTrans) const
std::vector< ESRecordIndex > const &	esGetTokenRecordIndicesVector (edm::Transition iTrans) const
ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesWhoseProductsAreConsumed (std::array< std::vector< ModuleDescription const *> *, NumBranchTypes > &modulesAll, std::vector< ModuleProcessName > &modulesInPreviousProcesses, ProductRegistry const &preg, std::map< std::string, ModuleDescription const *> const &labelsToDesc, std::string const &processName) const
EDConsumerBase const &	operator= (EDConsumerBase const &)=delete
EDConsumerBase &	operator= (EDConsumerBase &&)=default
bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	selectInputProcessBlocks (ProductRegistry const &productRegistry, ProcessBlockHelperBase const &processBlockHelperBase)
ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const
void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)
virtual	~EDConsumerBase () noexcept(false)

Private Member Functions
void	produce (edm::Event &, const edm::EventSetup &) override

Private Attributes
std::map< std::string, std::map< std::string, TF1 > >	all_nvtx_to_PU_sub_funcs
const double	barrelSF
const bool	debug
const edm::ESGetToken< CaloTPGTranscoder, CaloTPGRecord >	decoderTag_
std::map< std::string, TF1 >	ecal_nvtx_to_PU_sub_funcs
const double	EcalTpEtMin
std::map< std::string, TF1 >	hcal_nvtx_to_PU_sub_funcs
const edm::EDGetTokenT< HcalTrigPrimDigiCollection >	hcalToken_
edm::Handle< HcalTrigPrimDigiCollection >	hcalTowerHandle
const double	HcalTpEtMin
std::map< std::string, TF1 >	hf_nvtx_to_PU_sub_funcs
const double	hfSF
const double	HFTpEtMin
std::map< std::string, TF1 >	hgcalEM_nvtx_to_PU_sub_funcs
const double	HGCalEmTpEtMin
std::map< std::string, TF1 >	hgcalHad_nvtx_to_PU_sub_funcs
const double	HGCalHadTpEtMin
const double	hgcalSF
l1t::HGCalTowerBxCollection	hgcalTowers
edm::Handle< l1t::HGCalTowerBxCollection >	hgcalTowersHandle
const edm::EDGetTokenT< l1t::HGCalTowerBxCollection >	hgcalTowersToken_
edm::Handle< l1tp2::CaloTowerCollection >	l1CaloTowerHandle
const edm::EDGetTokenT< l1tp2::CaloTowerCollection >	l1TowerToken_
std::map< std::string, TF1 >	nHits_to_nvtx_funcs
std::vector< edm::ParameterSet >	nHits_to_nvtx_params
std::vector< edm::ParameterSet >	nvtx_to_PU_sub_params
const double	puThreshold
const double	puThresholdEcalMax
const double	puThresholdEcalMin
const double	puThresholdHcalMax
const double	puThresholdHcalMin
const double	puThresholdHFMax
const double	puThresholdHFMin
const double	puThresholdHGCalEMMax
const double	puThresholdHGCalEMMin
const double	puThresholdHGCalHadMax
const double	puThresholdHGCalHadMin
const double	puThresholdL1eg
const bool	skipCalibrations

Additional Inherited Members
Public Types inherited from edm::one::EDProducerBase
typedef EDProducerBase	ModuleType
Public Types inherited from edm::ProducerBase
using	ModuleToResolverIndicies = std::unordered_multimap< std::string, std::tuple< edm::TypeID const *, const char *, edm::ProductResolverIndex > >
typedef ProductRegistryHelper::TypeLabelList	TypeLabelList
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::one::EDProducerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)
Protected Member Functions inherited from edm::ProducerBase
template<Transition Tr = Transition::Event>
auto	produces (std::string instanceName) noexcept
	declare what type of product will make and with which optional label More...
template<Transition B>
BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)
template<BranchType B>
BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)
BranchAliasSetter	produces (const TypeID &id, std::string instanceName=std::string(), bool recordProvenance=true)
template<typename ProductType , Transition B>
BranchAliasSetterT< ProductType >	produces (std::string instanceName)
template<class ProductType >
BranchAliasSetterT< ProductType >	produces ()
template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces (std::string instanceName)
template<typename ProductType , BranchType B>
BranchAliasSetterT< ProductType >	produces ()
template<class ProductType >
BranchAliasSetterT< ProductType >	produces (std::string instanceName)
template<typename ProductType , Transition B>
BranchAliasSetterT< ProductType >	produces ()
template<Transition Tr = Transition::Event>
auto	produces () noexcept
ProducesCollector	producesCollector ()
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B >	consumes (edm::InputTag tag) noexcept
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)
ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...
template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()
void	consumesMany (const TypeToGet &id)
template<BranchType B>
void	consumesMany (const TypeToGet &id)
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes ()
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)
template<Transition Tr = Transition::Event>
constexpr auto	esConsumes ()
template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag)
template<Transition Tr = Transition::Event>
ESGetTokenGeneric	esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
	Used with EventSetupRecord::doGet. More...
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
void	resetItemsToGetFrom (BranchType iType)

Detailed Description

Description: Take the calibrated unclustered ECAL energy and total HCAL energy associated with the L1CaloTower collection output from L1EGammaCrystalsEmulatorProducer: l1CaloTowerCollection, "L1CaloTowerCollection"

as well as HGCal Tower level inputs: BXVector<l1t::HGCalTower> "hgcalTriggerPrimitiveDigiProducer" "tower" "HLT"
and HCAL HF inputs from: edm::SortedCollection<HcalTriggerPrimitiveDigi,edm::StrictWeakOrdering<HcalTriggerPrimitiveDigi> > "simHcalTriggerPrimitiveDigis" "" "HLT"

Implement PU-based calibrations which scale down the ET in the towers based on mapping nTowers with ECAL(HCAL) ET <= defined PU threshold. This value has been shown to be similar between TTbar, QCD, and minBias samples. This allows a prediction of nvtx. Which can be mapped to the total minBias energy in an eta slice of the detector. Subtract the total estimated minBias energy per eta slice divided by nTowers in that eta slice from each trigger tower in that eta slice.

This is all ECAL / HCAL specific or EM vs. Hadronic for HGCal.

Implementation: [Notes on implementation]

Definition at line 63 of file L1TowerCalibrator.cc.

Constructor & Destructor Documentation

L1TowerCalibrator()

L1TowerCalibrator::L1TowerCalibrator ( const edm::ParameterSet &  iConfig )

explicit

Definition at line 118 of file L1TowerCalibrator.cc.

References all_nvtx_to_PU_sub_funcs, debug, ecal_nvtx_to_PU_sub_funcs, hcal_nvtx_to_PU_sub_funcs, hf_nvtx_to_PU_sub_funcs, hgcalEM_nvtx_to_PU_sub_funcs, hgcalHad_nvtx_to_PU_sub_funcs, mps_fire::i, L1TowerCalibrationProducer_cfi::iEta, nHits_to_nvtx_funcs, nHits_to_nvtx_params, nvtx_to_PU_sub_params, LaserDQM_cfg::p1, SiStripOfflineCRack_cfg::p2, muonDTDigis_cfi::pset, AlCaHLTBitMon_QueryRunRegistry::string, and parallelization::uint.

    : HcalTpEtMin(iConfig.getParameter<double>("HcalTpEtMin")),
      EcalTpEtMin(iConfig.getParameter<double>("EcalTpEtMin")),
      HGCalHadTpEtMin(iConfig.getParameter<double>("HGCalHadTpEtMin")),
      HGCalEmTpEtMin(iConfig.getParameter<double>("HGCalEmTpEtMin")),
      HFTpEtMin(iConfig.getParameter<double>("HFTpEtMin")),
      puThreshold(iConfig.getParameter<double>("puThreshold")),
      puThresholdL1eg(iConfig.getParameter<double>("puThresholdL1eg")),
      puThresholdHcalMin(iConfig.getParameter<double>("puThresholdHcalMin")),
      puThresholdHcalMax(iConfig.getParameter<double>("puThresholdHcalMax")),
      puThresholdEcalMin(iConfig.getParameter<double>("puThresholdEcalMin")),
      puThresholdEcalMax(iConfig.getParameter<double>("puThresholdEcalMax")),
      puThresholdHGCalEMMin(iConfig.getParameter<double>("puThresholdHGCalEMMin")),
      puThresholdHGCalEMMax(iConfig.getParameter<double>("puThresholdHGCalEMMax")),
      puThresholdHGCalHadMin(iConfig.getParameter<double>("puThresholdHGCalHadMin")),
      puThresholdHGCalHadMax(iConfig.getParameter<double>("puThresholdHGCalHadMax")),
      puThresholdHFMin(iConfig.getParameter<double>("puThresholdHFMin")),
      puThresholdHFMax(iConfig.getParameter<double>("puThresholdHFMax")),
      barrelSF(iConfig.getParameter<double>("barrelSF")),
      hgcalSF(iConfig.getParameter<double>("hgcalSF")),
      hfSF(iConfig.getParameter<double>("hfSF")),
      debug(iConfig.getParameter<bool>("debug")),
      skipCalibrations(iConfig.getParameter<bool>("skipCalibrations")),
      l1TowerToken_(consumes<l1tp2::CaloTowerCollection>(iConfig.getParameter<edm::InputTag>("l1CaloTowers"))),
      hgcalTowersToken_(
          consumes<l1t::HGCalTowerBxCollection>(iConfig.getParameter<edm::InputTag>("L1HgcalTowersInputTag"))),
      hcalToken_(consumes<HcalTrigPrimDigiCollection>(iConfig.getParameter<edm::InputTag>("hcalDigis"))),
      decoderTag_(esConsumes<CaloTPGTranscoder, CaloTPGRecord>(edm::ESInputTag("", ""))),
      nHits_to_nvtx_params(iConfig.getParameter<std::vector<edm::ParameterSet> >("nHits_to_nvtx_params")),
      nvtx_to_PU_sub_params(iConfig.getParameter<std::vector<edm::ParameterSet> >("nvtx_to_PU_sub_params")) {
  // Initialize the nHits --> nvtx functions
  for (uint i = 0; i < nHits_to_nvtx_params.size(); i++) {
    edm::ParameterSet* pset = &nHits_to_nvtx_params.at(i);
    std::string calo = pset->getParameter<std::string>("fit");
    nHits_to_nvtx_funcs[calo.c_str()] = TF1(calo.c_str(), "[0] + [1] * x");
    nHits_to_nvtx_funcs[calo.c_str()].SetParameter(0, pset->getParameter<std::vector<double> >("params").at(0));
    nHits_to_nvtx_funcs[calo.c_str()].SetParameter(1, pset->getParameter<std::vector<double> >("params").at(1));

    if (debug) {
      printf(
          "nHits_to_nvtx_params[%i]\n \
                fit: %s \n \
                p1: %f \n \
                p2 %f \n",
          i,
          calo.c_str(),
          nHits_to_nvtx_funcs[calo.c_str()].GetParameter(0),
          nHits_to_nvtx_funcs[calo.c_str()].GetParameter(1));
    }
  }

  // Initialize the nvtx --> PU subtraction functions
  all_nvtx_to_PU_sub_funcs["ecal"] = ecal_nvtx_to_PU_sub_funcs;
  all_nvtx_to_PU_sub_funcs["hcal"] = hcal_nvtx_to_PU_sub_funcs;
  all_nvtx_to_PU_sub_funcs["hgcalEM"] = hgcalEM_nvtx_to_PU_sub_funcs;
  all_nvtx_to_PU_sub_funcs["hgcalHad"] = hgcalHad_nvtx_to_PU_sub_funcs;
  all_nvtx_to_PU_sub_funcs["hf"] = hf_nvtx_to_PU_sub_funcs;

  for (uint i = 0; i < nvtx_to_PU_sub_params.size(); i++) {
    edm::ParameterSet* pset = &nvtx_to_PU_sub_params.at(i);
    std::string calo = pset->getParameter<std::string>("calo");
    std::string iEta = pset->getParameter<std::string>("iEta");
    double p1 = pset->getParameter<std::vector<double> >("params").at(0);
    double p2 = pset->getParameter<std::vector<double> >("params").at(1);

    all_nvtx_to_PU_sub_funcs[calo.c_str()][iEta.c_str()] = TF1(calo.c_str(), "[0] + [1] * x");
    all_nvtx_to_PU_sub_funcs[calo.c_str()][iEta.c_str()].SetParameter(0, p1);
    all_nvtx_to_PU_sub_funcs[calo.c_str()][iEta.c_str()].SetParameter(1, p2);

    if (debug) {
      printf(
          "nvtx_to_PU_sub_params[%i]\n \
                sub detector: %s \n \
                iEta: %s \n \
                p1: %f \n \
                p2 %f \n",
          i,
          calo.c_str(),
          iEta.c_str(),
          p1,
          p2);
    }
  }

  // Our two outputs, calibrated towers and estimated nvtx for fun
  produces<l1tp2::CaloTowerCollection>("L1CaloTowerCalibratedCollection");
  produces<double>("EstimatedNvtx");
}

Member Function Documentation

produce()

void L1TowerCalibrator::produce ( edm::Event &  iEvent, const edm::EventSetup &  iSetup  )

overrideprivatevirtual

Implements edm::one::EDProducerBase.

Definition at line 207 of file L1TowerCalibrator.cc.

References funct::abs(), all_nvtx_to_PU_sub_funcs, barrelSF, BXVector< T >::begin(), debug, decoderTag_, l1tp2::CaloTower::ecalTowerEt(), EcalTpEtMin, BXVector< T >::end(), EgHLTOffHistBins_cfi::et, edm::EventSetup::getData(), hcalToken_, l1tp2::CaloTower::hcalTowerEt(), hcalTowerHandle, HcalTpEtMin, hfSF, HFTpEtMin, HGCalEmTpEtMin, HGCalHadTpEtMin, hgcalSF, hgcalTowers, hgcalTowersHandle, hgcalTowersToken_, hit::id, LEDCalibrationChannels::ieta, iEvent, createfilelist::int, LEDCalibrationChannels::iphi, l1t::CaloTools::kHFBegin, l1t::CaloTools::kHFEnd, l1CaloTowerHandle, l1TowerToken_, eostools::move(), nHits_to_nvtx_funcs, edm::Handle< T >::product(), puThresholdEcalMax, puThresholdEcalMin, puThresholdHcalMax, puThresholdHcalMin, puThresholdHFMax, puThresholdHFMin, puThresholdHGCalEMMax, puThresholdHGCalEMMin, puThresholdHGCalHadMax, puThresholdHGCalHadMin, l1tp2::CaloTower::setEcalTowerEt(), l1tp2::CaloTower::setHcalTowerEt(), l1tp2::CaloTower::setIsBarrel(), l1tp2::CaloTower::setL1egStandaloneIso(), l1tp2::CaloTower::setL1egStandaloneSS(), l1tp2::CaloTower::setL1egTowerEt(), l1tp2::CaloTower::setL1egTrkIso(), l1tp2::CaloTower::setL1egTrkSS(), l1tp2::CaloTower::setNL1eg(), l1tp2::CaloTower::setTowerEta(), l1tp2::CaloTower::setTowerIEta(), l1tp2::CaloTower::setTowerIPhi(), l1tp2::CaloTower::setTowerPhi(), skipCalibrations, l1tp2::CaloTower::towerEta(), l1t::CaloTools::towerEta(), l1tp2::CaloTower::towerIEta(), l1tp2::CaloTower::towerIPhi(), l1tp2::CaloTower::towerPhi(), and l1t::CaloTools::towerPhi().

                                                                             {
  // Estimated number of vertices used for calibration estimattion
  std::unique_ptr<double> EstimatedNvtx(new double);
  // Calibrated output collection
  std::unique_ptr<l1tp2::CaloTowerCollection> L1CaloTowerCalibratedCollection(new l1tp2::CaloTowerCollection);

  // Load the ECAL+HCAL tower sums coming from L1EGammaCrystalsEmulatorProducer.cc
  iEvent.getByToken(l1TowerToken_, l1CaloTowerHandle);

  // HGCal info
  iEvent.getByToken(hgcalTowersToken_, hgcalTowersHandle);
  hgcalTowers = (*hgcalTowersHandle.product());

  // HF Tower info
  iEvent.getByToken(hcalToken_, hcalTowerHandle);

  // Barrel ECAL (unclustered) and HCAL
  for (auto& hit : *l1CaloTowerHandle.product()) {
    l1tp2::CaloTower l1Hit;
    l1Hit.setEcalTowerEt(hit.ecalTowerEt());
    l1Hit.setHcalTowerEt(hit.hcalTowerEt());
    l1Hit.setL1egTowerEt(hit.l1egTowerEt());
    // Add min ET thresholds for tower ET
    if (l1Hit.ecalTowerEt() < EcalTpEtMin)
      l1Hit.setEcalTowerEt(0.0);
    if (l1Hit.hcalTowerEt() < HcalTpEtMin)
      l1Hit.setHcalTowerEt(0.0);
    l1Hit.setTowerIEta(hit.towerIEta());
    l1Hit.setTowerIPhi(hit.towerIPhi());
    l1Hit.setTowerEta(hit.towerEta());
    l1Hit.setTowerPhi(hit.towerPhi());
    l1Hit.setIsBarrel(hit.isBarrel());
    l1Hit.setNL1eg(hit.nL1eg());
    l1Hit.setL1egTrkSS(hit.l1egTrkSS());
    l1Hit.setL1egTrkIso(hit.l1egTrkIso());
    l1Hit.setL1egStandaloneSS(hit.l1egStandaloneSS());
    l1Hit.setL1egStandaloneIso(hit.l1egStandaloneIso());

    // FIXME There is an error in the L1EGammaCrystalsEmulatorProducer.cc which is
    // returning towers with minimal ECAL energy, and no HCAL energy with these
    // iEta/iPhi coordinates and eta = -88.653152 and phi = -99.000000.
    // Skip these for the time being until the upstream code has been debugged
    if ((int)l1Hit.towerIEta() == -1016 && (int)l1Hit.towerIPhi() == -962)
      continue;

    (*L1CaloTowerCalibratedCollection).push_back(l1Hit);
    if (debug)
      printf("Barrel tower iEta %i iPhi %i eta %f phi %f ecal_et %f hcal_et_sum %f\n",
             (int)l1Hit.towerIEta(),
             (int)l1Hit.towerIPhi(),
             l1Hit.towerEta(),
             l1Hit.towerPhi(),
             l1Hit.ecalTowerEt(),
             l1Hit.hcalTowerEt());
  }

  // Loop over HGCalTowers and create L1CaloTowers for them and add to collection
  // This iterator is taken from the PF P2 group
  // https://github.com/p2l1pfp/cmssw/blob/170808db68038d53794bc65fdc962f8fc337a24d/L1Trigger/Phase2L1ParticleFlow/plugins/L1TPFCaloProducer.cc#L278-L289
  for (auto it = hgcalTowers.begin(0), ed = hgcalTowers.end(0); it != ed; ++it) {
    // skip lowest ET towers
    if (it->etEm() < HGCalEmTpEtMin && it->etHad() < HGCalHadTpEtMin)
      continue;

    l1tp2::CaloTower l1Hit;
    // Set energies normally, but need to zero if below threshold
    if (it->etEm() < HGCalEmTpEtMin)
      l1Hit.setEcalTowerEt(0.);
    else
      l1Hit.setEcalTowerEt(it->etEm());

    if (it->etHad() < HGCalHadTpEtMin)
      l1Hit.setHcalTowerEt(0.);
    else
      l1Hit.setHcalTowerEt(it->etHad());

    l1Hit.setTowerEta(it->eta());
    l1Hit.setTowerPhi(it->phi());
    l1Hit.setTowerIEta(-98);  // -98 mean HGCal
    l1Hit.setTowerIPhi(-98);
    l1Hit.setIsBarrel(false);
    (*L1CaloTowerCalibratedCollection).push_back(l1Hit);
    if (debug)
      printf("HGCal tower iEta %i iPhi %i eta %f phi %f ecal_et %f hcal_et_sum %f\n",
             (int)l1Hit.towerIEta(),
             (int)l1Hit.towerIPhi(),
             l1Hit.towerEta(),
             l1Hit.towerPhi(),
             l1Hit.ecalTowerEt(),
             l1Hit.hcalTowerEt());
  }

  // Loop over Hcal HF tower inputs and create L1CaloTowers and add to
  // L1CaloTowerCalibratedCollection collection
  const auto& decoder = iSetup.getData(decoderTag_);
  for (const auto& hit : *hcalTowerHandle.product()) {
    HcalTrigTowerDetId id = hit.id();
    double et = decoder.hcaletValue(hit.id(), hit.t0());
    if (et < HFTpEtMin)
      continue;
    // Only doing HF so skip outside range
    if (abs(id.ieta()) < l1t::CaloTools::kHFBegin)
      continue;
    if (abs(id.ieta()) > l1t::CaloTools::kHFEnd)
      continue;

    l1tp2::CaloTower l1Hit;
    l1Hit.setEcalTowerEt(0.);
    l1Hit.setHcalTowerEt(et);
    l1Hit.setTowerEta(l1t::CaloTools::towerEta(id.ieta()));
    l1Hit.setTowerPhi(l1t::CaloTools::towerPhi(id.ieta(), id.iphi()));
    l1Hit.setTowerIEta(id.ieta());
    l1Hit.setTowerIPhi(id.iphi());
    l1Hit.setIsBarrel(false);
    (*L1CaloTowerCalibratedCollection).push_back(l1Hit);

    if (debug)
      printf("HCAL HF tower iEta %i iPhi %i eta %f phi %f ecal_et %f hcal_et_sum %f\n",
             (int)l1Hit.towerIEta(),
             (int)l1Hit.towerIPhi(),
             l1Hit.towerEta(),
             l1Hit.towerPhi(),
             l1Hit.ecalTowerEt(),
             l1Hit.hcalTowerEt());
  }

  // N Tower totals
  // For mapping to estimated nvtx in event
  int i_ecal_hits_leq_threshold = 0;
  int i_hgcalEM_hits_leq_threshold = 0;
  int i_hcal_hits_leq_threshold = 0;
  int i_hgcalHad_hits_leq_threshold = 0;
  int i_hf_hits_leq_threshold = 0;

  // Loop over the collection containing all hits
  // and calculate the number of hits falling into the
  // "less than or equal" nTowers variable which maps to
  // estimated number of vertices
  for (auto& l1CaloTower : (*L1CaloTowerCalibratedCollection)) {
    // Barrel ECAL
    if (l1CaloTower.ecalTowerEt() > 0. && l1CaloTower.towerIEta() != -98) {
      if (l1CaloTower.ecalTowerEt() <= puThresholdEcalMax && l1CaloTower.ecalTowerEt() >= puThresholdEcalMin) {
        i_ecal_hits_leq_threshold++;
      }
    }

    // HGCal EM
    if (l1CaloTower.ecalTowerEt() > 0. && l1CaloTower.towerIEta() == -98) {
      if (l1CaloTower.ecalTowerEt() <= puThresholdHGCalEMMax && l1CaloTower.ecalTowerEt() >= puThresholdHGCalEMMin) {
        i_hgcalEM_hits_leq_threshold++;
      }
    }

    // Barrel HCAL
    if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() != -98 &&
        abs(l1CaloTower.towerEta()) < 2.0)  // abs(eta) < 2 just keeps us out of HF
    {
      if (l1CaloTower.hcalTowerEt() <= puThresholdHcalMax && l1CaloTower.hcalTowerEt() >= puThresholdHcalMin) {
        i_hcal_hits_leq_threshold++;
      }
    }

    // HGCal Had
    if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() == -98) {
      if (l1CaloTower.hcalTowerEt() <= puThresholdHGCalHadMax && l1CaloTower.hcalTowerEt() >= puThresholdHGCalHadMin) {
        i_hgcalHad_hits_leq_threshold++;
      }
    }

    // HF
    if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() != -98 &&
        abs(l1CaloTower.towerEta()) > 2.0)  // abs(eta) > 2 keeps us out of barrel HF
    {
      if (l1CaloTower.hcalTowerEt() <= puThresholdHFMax && l1CaloTower.hcalTowerEt() >= puThresholdHFMin) {
        i_hf_hits_leq_threshold++;
      }
    }
  }

  // For each subdetector, map to the estimated number of vertices
  double ecal_nvtx = nHits_to_nvtx_funcs["ecal"].Eval(i_ecal_hits_leq_threshold);
  double hcal_nvtx = nHits_to_nvtx_funcs["hcal"].Eval(i_hcal_hits_leq_threshold);
  double hgcalEM_nvtx = nHits_to_nvtx_funcs["hgcalEM"].Eval(i_hgcalEM_hits_leq_threshold);
  double hgcalHad_nvtx = nHits_to_nvtx_funcs["hgcalHad"].Eval(i_hgcalHad_hits_leq_threshold);
  double hf_nvtx = nHits_to_nvtx_funcs["hf"].Eval(i_hf_hits_leq_threshold);
  // Make sure all values are >= 0
  if (ecal_nvtx < 0)
    ecal_nvtx = 0;
  if (hcal_nvtx < 0)
    hcal_nvtx = 0;
  if (hgcalEM_nvtx < 0)
    hgcalEM_nvtx = 0;
  if (hgcalHad_nvtx < 0)
    hgcalHad_nvtx = 0;
  if (hf_nvtx < 0)
    hf_nvtx = 0;
  // Best estimate is avg of all except HF.
  // This is b/c HF currently has such poor prediction power, it only degrades the avg result
  // NEW, with 10_3_X, hgcal and HF has the best results based on the values I took...
  // skip ECAL and HCAL
  //*EstimatedNvtx = ( ecal_nvtx + hcal_nvtx + hgcalEM_nvtx + hgcalHad_nvtx + hf_nvtx ) / 3.;
  *EstimatedNvtx = (hgcalEM_nvtx + hgcalHad_nvtx + hf_nvtx) / 3.;

  if (debug) {
    double lumi = iEvent.eventAuxiliary().luminosityBlock();
    double event = iEvent.eventAuxiliary().event();

    printf(
        "L1TowerCalibrater: lumi %.0f evt %.0f nTowers for subdetecters \
            \nECAL:      %i --> nvtx = %.1f \
            \nHGCal EM:  %i --> nvtx = %.1f \
            \nHCAL:      %i --> nvtx = %.1f \
            \nHGCal Had: %i --> nvtx = %.1f \
            \nHCAL HF:   %i --> nvtx = %.1f \
            \nEstimated Nvtx = %.1f\n",
        lumi,
        event,
        i_ecal_hits_leq_threshold,
        ecal_nvtx,
        i_hgcalEM_hits_leq_threshold,
        hgcalEM_nvtx,
        i_hcal_hits_leq_threshold,
        hcal_nvtx,
        i_hgcalHad_hits_leq_threshold,
        hgcalHad_nvtx,
        i_hf_hits_leq_threshold,
        hf_nvtx,
        *EstimatedNvtx);
  }

  // Use estimated number of vertices to subtract off PU contributions
  // to each and every hit. In cases where the energy would go negative,
  // limit this to zero.
  if (!skipCalibrations)  // skipCalibrations simply passes the towers through
  {
    for (auto& l1CaloTower : (*L1CaloTowerCalibratedCollection)) {
      // Barrel ECAL eta slices
      if (l1CaloTower.ecalTowerEt() > 0. && l1CaloTower.towerIEta() != -98) {
        if (abs(l1CaloTower.towerIEta()) <= 3) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er1to3"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 6 && abs(l1CaloTower.towerIEta()) >= 4) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er4to6"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 9 && abs(l1CaloTower.towerIEta()) >= 7) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er7to9"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 12 && abs(l1CaloTower.towerIEta()) >= 10) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er10to12"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 15 && abs(l1CaloTower.towerIEta()) >= 13) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er13to15"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 18 && abs(l1CaloTower.towerIEta()) >= 16) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["ecal"]["er16to18"].Eval(*EstimatedNvtx) * barrelSF);
        }
      }

      // HGCal EM eta slices
      if (l1CaloTower.ecalTowerEt() > 0. && l1CaloTower.towerIEta() == -98) {
        if (abs(l1CaloTower.towerEta()) <= 1.8) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalEM"]["er1p4to1p8"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.1 && abs(l1CaloTower.towerEta()) > 1.8) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalEM"]["er1p8to2p1"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.4 && abs(l1CaloTower.towerEta()) > 2.1) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalEM"]["er2p1to2p4"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.7 && abs(l1CaloTower.towerEta()) > 2.4) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalEM"]["er2p4to2p7"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 3.1 && abs(l1CaloTower.towerEta()) > 2.7) {
          l1CaloTower.setEcalTowerEt(l1CaloTower.ecalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalEM"]["er2p7to3p1"].Eval(*EstimatedNvtx) * hgcalSF);
        }
      }

      // Barrel HCAL eta slices
      if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() != -98 &&
          abs(l1CaloTower.towerEta()) < 2.0)  // abs(eta) < 2 just keeps us out of HF
      {
        if (abs(l1CaloTower.towerIEta()) <= 3) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er1to3"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 6 && abs(l1CaloTower.towerIEta()) >= 4) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er4to6"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 9 && abs(l1CaloTower.towerIEta()) >= 7) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er7to9"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 12 && abs(l1CaloTower.towerIEta()) >= 10) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er10to12"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 15 && abs(l1CaloTower.towerIEta()) >= 13) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er13to15"].Eval(*EstimatedNvtx) * barrelSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 18 && abs(l1CaloTower.towerIEta()) >= 16) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hcal"]["er16to18"].Eval(*EstimatedNvtx) * barrelSF);
        }
      }

      // HGCal Had eta slices
      if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() == -98) {
        if (abs(l1CaloTower.towerEta()) <= 1.8) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalHad"]["er1p4to1p8"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.1 && abs(l1CaloTower.towerEta()) > 1.8) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalHad"]["er1p8to2p1"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.4 && abs(l1CaloTower.towerEta()) > 2.1) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalHad"]["er2p1to2p4"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 2.7 && abs(l1CaloTower.towerEta()) > 2.4) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalHad"]["er2p4to2p7"].Eval(*EstimatedNvtx) * hgcalSF);
        }
        if (abs(l1CaloTower.towerEta()) <= 3.1 && abs(l1CaloTower.towerEta()) > 2.7) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hgcalHad"]["er2p7to3p1"].Eval(*EstimatedNvtx) * hgcalSF);
        }
      }

      // HF eta slices
      if (l1CaloTower.hcalTowerEt() > 0. && l1CaloTower.towerIEta() != -98 &&
          abs(l1CaloTower.towerEta()) > 2.0)  // abs(eta) > 2 keeps us out of barrel HF
      {
        if (abs(l1CaloTower.towerIEta()) <= 33 && abs(l1CaloTower.towerIEta()) >= 29) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hf"]["er29to33"].Eval(*EstimatedNvtx) * hfSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 37 && abs(l1CaloTower.towerIEta()) >= 34) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hf"]["er34to37"].Eval(*EstimatedNvtx) * hfSF);
        }
        if (abs(l1CaloTower.towerIEta()) <= 41 && abs(l1CaloTower.towerIEta()) >= 38) {
          l1CaloTower.setHcalTowerEt(l1CaloTower.hcalTowerEt() -
                                     all_nvtx_to_PU_sub_funcs["hf"]["er38to41"].Eval(*EstimatedNvtx) * hfSF);
        }
      }

      // Make sure none are negative
      if (l1CaloTower.ecalTowerEt() < 0.)
        l1CaloTower.setEcalTowerEt(0.);
      if (l1CaloTower.hcalTowerEt() < 0.)
        l1CaloTower.setHcalTowerEt(0.);
    }
  }

  iEvent.put(std::move(EstimatedNvtx), "EstimatedNvtx");
  iEvent.put(std::move(L1CaloTowerCalibratedCollection), "L1CaloTowerCalibratedCollection");
}

Member Data Documentation

all_nvtx_to_PU_sub_funcs

std::map<std::string, std::map<std::string, TF1> > L1TowerCalibrator::all_nvtx_to_PU_sub_funcs

private

Definition at line 115 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator(), and produce().

barrelSF

const double L1TowerCalibrator::barrelSF

private

Definition at line 87 of file L1TowerCalibrator.cc.

Referenced by produce().

debug

const bool L1TowerCalibrator::debug

private

Definition at line 90 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator(), runTauIdMVA.TauIDEmbedder::loadMVA_WPs_run2_2017(), produce(), and runTauIdMVA.TauIDEmbedder::runTauID().

decoderTag_

const edm::ESGetToken<CaloTPGTranscoder, CaloTPGRecord> L1TowerCalibrator::decoderTag_

private

Definition at line 102 of file L1TowerCalibrator.cc.

Referenced by produce().

ecal_nvtx_to_PU_sub_funcs

std::map<std::string, TF1> L1TowerCalibrator::ecal_nvtx_to_PU_sub_funcs

private

Definition at line 110 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

EcalTpEtMin

const double L1TowerCalibrator::EcalTpEtMin

private

Definition at line 71 of file L1TowerCalibrator.cc.

Referenced by produce().

hcal_nvtx_to_PU_sub_funcs

std::map<std::string, TF1> L1TowerCalibrator::hcal_nvtx_to_PU_sub_funcs

private

Definition at line 111 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

hcalToken_

const edm::EDGetTokenT<HcalTrigPrimDigiCollection> L1TowerCalibrator::hcalToken_

private

Definition at line 100 of file L1TowerCalibrator.cc.

Referenced by produce().

hcalTowerHandle

edm::Handle<HcalTrigPrimDigiCollection> L1TowerCalibrator::hcalTowerHandle

private

Definition at line 101 of file L1TowerCalibrator.cc.

Referenced by produce().

HcalTpEtMin

const double L1TowerCalibrator::HcalTpEtMin

private

Definition at line 70 of file L1TowerCalibrator.cc.

Referenced by produce().

hf_nvtx_to_PU_sub_funcs

std::map<std::string, TF1> L1TowerCalibrator::hf_nvtx_to_PU_sub_funcs

private

Definition at line 114 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

hfSF

const double L1TowerCalibrator::hfSF

private

Definition at line 89 of file L1TowerCalibrator.cc.

Referenced by produce().

HFTpEtMin

const double L1TowerCalibrator::HFTpEtMin

private

Definition at line 74 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalEM_nvtx_to_PU_sub_funcs

std::map<std::string, TF1> L1TowerCalibrator::hgcalEM_nvtx_to_PU_sub_funcs

private

Definition at line 112 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

HGCalEmTpEtMin

const double L1TowerCalibrator::HGCalEmTpEtMin

private

Definition at line 73 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalHad_nvtx_to_PU_sub_funcs

std::map<std::string, TF1> L1TowerCalibrator::hgcalHad_nvtx_to_PU_sub_funcs

private

Definition at line 113 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

HGCalHadTpEtMin

const double L1TowerCalibrator::HGCalHadTpEtMin

private

Definition at line 72 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalSF

const double L1TowerCalibrator::hgcalSF

private

Definition at line 88 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalTowers

l1t::HGCalTowerBxCollection L1TowerCalibrator::hgcalTowers

private

Definition at line 98 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalTowersHandle

edm::Handle<l1t::HGCalTowerBxCollection> L1TowerCalibrator::hgcalTowersHandle

private

Definition at line 97 of file L1TowerCalibrator.cc.

Referenced by produce().

hgcalTowersToken_

const edm::EDGetTokenT<l1t::HGCalTowerBxCollection> L1TowerCalibrator::hgcalTowersToken_

private

Definition at line 96 of file L1TowerCalibrator.cc.

Referenced by produce().

l1CaloTowerHandle

edm::Handle<l1tp2::CaloTowerCollection> L1TowerCalibrator::l1CaloTowerHandle

private

Definition at line 94 of file L1TowerCalibrator.cc.

Referenced by produce().

l1TowerToken_

const edm::EDGetTokenT<l1tp2::CaloTowerCollection> L1TowerCalibrator::l1TowerToken_

private

Definition at line 93 of file L1TowerCalibrator.cc.

Referenced by produce().

nHits_to_nvtx_funcs

std::map<std::string, TF1> L1TowerCalibrator::nHits_to_nvtx_funcs

private

Definition at line 106 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator(), and produce().

nHits_to_nvtx_params

std::vector<edm::ParameterSet> L1TowerCalibrator::nHits_to_nvtx_params

private

Definition at line 105 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

nvtx_to_PU_sub_params

std::vector<edm::ParameterSet> L1TowerCalibrator::nvtx_to_PU_sub_params

private

Definition at line 109 of file L1TowerCalibrator.cc.

Referenced by L1TowerCalibrator().

puThreshold

const double L1TowerCalibrator::puThreshold

private

Definition at line 75 of file L1TowerCalibrator.cc.

puThresholdEcalMax

const double L1TowerCalibrator::puThresholdEcalMax

private

Definition at line 80 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdEcalMin

const double L1TowerCalibrator::puThresholdEcalMin

private

Definition at line 79 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHcalMax

const double L1TowerCalibrator::puThresholdHcalMax

private

Definition at line 78 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHcalMin

const double L1TowerCalibrator::puThresholdHcalMin

private

Definition at line 77 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHFMax

const double L1TowerCalibrator::puThresholdHFMax

private

Definition at line 86 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHFMin

const double L1TowerCalibrator::puThresholdHFMin

private

Definition at line 85 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHGCalEMMax

const double L1TowerCalibrator::puThresholdHGCalEMMax

private

Definition at line 82 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHGCalEMMin

const double L1TowerCalibrator::puThresholdHGCalEMMin

private

Definition at line 81 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHGCalHadMax

const double L1TowerCalibrator::puThresholdHGCalHadMax

private

Definition at line 84 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdHGCalHadMin

const double L1TowerCalibrator::puThresholdHGCalHadMin

private

Definition at line 83 of file L1TowerCalibrator.cc.

Referenced by produce().

puThresholdL1eg

const double L1TowerCalibrator::puThresholdL1eg

private

Definition at line 76 of file L1TowerCalibrator.cc.

skipCalibrations

const bool L1TowerCalibrator::skipCalibrations

private

Definition at line 91 of file L1TowerCalibrator.cc.

Referenced by produce().