#include <HGCalShowerShape.h>

Classes
struct	DeltaPhi

Public Types
typedef math::XYZTLorentzVector	LorentzVector

Public Member Functions
int	bitmap (const l1t::HGCalMulticluster &c3d, int start=1, int end=14, float threshold=0) const

int	coreShowerLength (const l1t::HGCalMulticluster &c3d, const HGCalTriggerGeometryBase &triggerGeometry) const

float	eMax (const l1t::HGCalMulticluster &c3d) const

void	fillShapes (l1t::HGCalMulticluster &, const HGCalTriggerGeometryBase &) const

int	firstLayer (const l1t::HGCalMulticluster &c3d) const

	HGCalShowerShape ()

	HGCalShowerShape (const edm::ParameterSet &conf)

int	lastLayer (const l1t::HGCalMulticluster &c3d) const

int	maxLayer (const l1t::HGCalMulticluster &c3d) const

float	meanZ (const l1t::HGCalMulticluster &c3d) const

float	percentileLayer (const l1t::HGCalMulticluster &c3d, const HGCalTriggerGeometryBase &triggerGeometry, float quantile=0.5) const

float	percentileTriggerCells (const l1t::HGCalMulticluster &c3d, float quantile=0.5) const

void	setGeometry (const HGCalTriggerGeometryBase *const geom)

int	showerLength (const l1t::HGCalMulticluster &c3d) const

float	sigmaEtaEtaMax (const l1t::HGCalMulticluster &c3d) const

float	sigmaEtaEtaTot (const l1t::HGCalMulticluster &c3d) const

float	sigmaEtaEtaTot (const l1t::HGCalCluster &c2d) const

float	sigmaPhiPhiMax (const l1t::HGCalMulticluster &c3d) const

float	sigmaPhiPhiTot (const l1t::HGCalMulticluster &c3d) const

float	sigmaPhiPhiTot (const l1t::HGCalCluster &c2d) const

float	sigmaRRMax (const l1t::HGCalMulticluster &c3d) const

float	sigmaRRMean (const l1t::HGCalMulticluster &c3d, float radius=5.) const

float	sigmaRRTot (const l1t::HGCalMulticluster &c3d) const

float	sigmaRRTot (const l1t::HGCalCluster &c2d) const

float	sigmaZZ (const l1t::HGCalMulticluster &c3d) const

float	sumLayers (const l1t::HGCalMulticluster &c3d, int start=1, int end=0) const

float	varEtaEta (const l1t::HGCalMulticluster &c3d) const

float	varPhiPhi (const l1t::HGCalMulticluster &c3d) const

float	varRR (const l1t::HGCalMulticluster &c3d) const

float	varZZ (const l1t::HGCalMulticluster &c3d) const

	~HGCalShowerShape ()

Private Member Functions
float	meanX (const std::vector< pair< float, float >> &energy_X_tc) const

template<typename T , typename Tref >
bool	pass (const T &obj, const Tref &ref) const

float	sigmaPhiPhi (const std::vector< pair< float, float >> &energy_phi_tc, const float phi_cluster) const

float	sigmaXX (const std::vector< pair< float, float >> &energy_X_tc, const float X_cluster) const

float	varPhiPhi (const std::vector< pair< float, float >> &energy_phi_tc, const float phi_cluster) const

template<typename Delta = std::minus<float>>
float	varXX (const std::vector< pair< float, float >> &energy_X_tc, const float X_cluster) const

Private Attributes
double	distance_ = 1.

double	threshold_ = 0.

HGCalTriggerTools	triggerTools_

Detailed Description

Definition at line 12 of file HGCalShowerShape.h.

Member Typedef Documentation

◆ LorentzVector

typedef math::XYZTLorentzVector HGCalShowerShape::LorentzVector

Definition at line 14 of file HGCalShowerShape.h.

Constructor & Destructor Documentation

◆ HGCalShowerShape() [1/2]

HGCalShowerShape::HGCalShowerShape ( )

inline

Definition at line 16 of file HGCalShowerShape.h.

16 : threshold_(0.) {}

HGCalShowerShape::threshold_

double threshold_

Definition: HGCalShowerShape.h:107

◆ HGCalShowerShape() [2/2]

HGCalShowerShape::HGCalShowerShape ( const edm::ParameterSet & conf )

Definition at line 9 of file HGCalShowerShape.cc.

10 : threshold_(conf.getParameter<double>("shape_threshold")),

11 distance_(conf.getParameter<double>("shape_distance")) {}

edm::ParameterSet::getParameter

T getParameter(std::string const &) const

Definition: ParameterSet.h:307

HGCalShowerShape::distance_

double distance_

Definition: HGCalShowerShape.h:108

HGCalShowerShape::threshold_

double threshold_

Definition: HGCalShowerShape.h:107

◆ ~HGCalShowerShape()

HGCalShowerShape::~HGCalShowerShape ( )

inline

Definition at line 19 of file HGCalShowerShape.h.

19 {}

Member Function Documentation

◆ bitmap()

int HGCalShowerShape::bitmap	(	const l1t::HGCalMulticluster &	c3d,
		int	start = `1`,
		int	end = `14`,
		float	threshold = `0`
	)		const

Definition at line 552 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), mps_fire::end, HGCalTriggerTools::getTriggerGeometry(), mps_fire::i, HGCalTriggerGeometryBase::lastTriggerLayer(), nano_mu_digi_cff::layer, hgcalTBTopologyTester_cfi::layers, pass(), DiMuonV_cfg::threshold, caloTruthCellsProducer_cfi::triggerCells, HGCalTriggerTools::triggerLayer(), and triggerTools_.

Referenced by fillShapes().

                                                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   unsigned nlayers = triggerTools_.getTriggerGeometry()->lastTriggerLayer();
   std::vector<double> layers(nlayers, 0);
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       unsigned layer = triggerTools_.triggerLayer(id_tc.second->detId());
       if (layer == 0 || layer > nlayers)
         continue;
       layers[layer - 1] += id_tc.second->pt();  //shift by -1 because layer 0 doesn't exist
     }
   }
   uint32_t bitmap = 0;
   const int bitmap_size = 32;
   if (start == 0) {
     edm::LogWarning("DataNotFound") << "Trying to read layer 0 that doesn't exist, defaulted start to layer 1";
     start = 1;
   }
   if ((end - start) + 1 > bitmap_size) {
     edm::LogWarning("TooMuchData") << " Specified bounds cannot fit into bitmap size, defaulting to 0.";
   } else {
     for (int i = start; i <= end; i++) {
       bitmap += (layers[i - 1] > threshold) << (end - (i));
     }
   }
   return bitmap;
 }

◆ coreShowerLength()

int HGCalShowerShape::coreShowerLength	(	const l1t::HGCalMulticluster &	c3d,
		const HGCalTriggerGeometryBase &	triggerGeometry
	)		const

Definition at line 81 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), ForwardEmpty, HFNose, HGCalTriggerTools::isNose(), nano_mu_digi_cff::layer, hgcalTBTopologyTester_cfi::layers, HGCalTriggerTools::layers(), pass(), HGCalTriggerGeometryBase::triggerLayer(), and triggerTools_.

Referenced by fillShapes().

                                                                                               {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   unsigned nlayers = triggerTools_.layers(ForwardSubdetector::ForwardEmpty);
   std::vector<bool> layers(nlayers);
   for (const auto& id_cluster : clustersPtrs) {
     if (!pass(*id_cluster.second, c3d))
       continue;
     unsigned layer = triggerGeometry.triggerLayer(id_cluster.second->detId());
     if (triggerTools_.isNose(id_cluster.second->detId()))
       nlayers = triggerTools_.layers(ForwardSubdetector::HFNose);
     else {
       nlayers = triggerTools_.layers(ForwardSubdetector::ForwardEmpty);
     }
     if (layer == 0 || layer > nlayers)
       continue;
     layers[layer - 1] = true;  //layer 0 doesn't exist, so shift by -1
   }
   int length = 0;
   int maxlength = 0;
   for (bool layer : layers) {
     if (layer)
       length++;
     else
       length = 0;
     if (length > maxlength)
       maxlength = length;
   }
   return maxlength;
 }

◆ eMax()

float HGCalShowerShape::eMax ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 407 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), and triggerTools_.

Referenced by fillShapes().

                                                                   {
   std::unordered_map<int, float> layer_energy;
 
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   for (const auto& id_clu : clustersPtrs) {
     if (!pass(*id_clu.second, c3d))
       continue;
     unsigned layer = triggerTools_.layerWithOffset(id_clu.second->detId());
     layer_energy[layer] += id_clu.second->energy();
   }
 
   float EMax = 0;
 
   for (const auto& layer : layer_energy) {
     if (layer.second > EMax)
       EMax = layer.second;
   }
 
   return EMax;
 }

◆ fillShapes()

void HGCalShowerShape::fillShapes	(	l1t::HGCalMulticluster &	c3d,
		const HGCalTriggerGeometryBase &	triggerGeometry
	)		const

Definition at line 584 of file HGCalShowerShape.cc.

Referenced by HGCalMulticlusteringImpl::finalizeClusters(), HGCalHistoClusteringImpl::finalizeClusters(), and CaloTruthCellsProducer::produce().

                                                                                                                   {
   unsigned hcal_offset = triggerTools_.layers(ForwardSubdetector::HGCEE) / 2;
   unsigned lastlayer = triggerGeometry.lastTriggerLayer();
   const unsigned showermaxlayer = 7;
   c3d.setShowerLength(showerLength(c3d));
   c3d.setCoreShowerLength(coreShowerLength(c3d, triggerGeometry));
   c3d.setFirstLayer(firstLayer(c3d));
   c3d.setMaxLayer(maxLayer(c3d));
   c3d.setSigmaEtaEtaTot(sigmaEtaEtaTot(c3d));
   c3d.setSigmaEtaEtaMax(sigmaEtaEtaMax(c3d));
   c3d.setVarEtaEta(varEtaEta(c3d));
   c3d.setSigmaPhiPhiTot(sigmaPhiPhiTot(c3d));
   c3d.setSigmaPhiPhiMax(sigmaPhiPhiMax(c3d));
   c3d.setVarPhiPhi(varPhiPhi(c3d));
   c3d.setSigmaZZ(sigmaZZ(c3d));
   c3d.setVarZZ(varZZ(c3d));
   c3d.setSigmaRRTot(sigmaRRTot(c3d));
   c3d.setVarRR(varRR(c3d));
   c3d.setSigmaRRMax(sigmaRRMax(c3d));
   c3d.setSigmaRRMean(sigmaRRMean(c3d));
   c3d.setEMax(eMax(c3d));
   c3d.setZBarycenter(meanZ(c3d));
   c3d.setLayer10percent(percentileLayer(c3d, triggerGeometry, 0.10));
   c3d.setLayer50percent(percentileLayer(c3d, triggerGeometry, 0.50));
   c3d.setLayer90percent(percentileLayer(c3d, triggerGeometry, 0.90));
   c3d.setTriggerCells67percent(percentileTriggerCells(c3d, 0.67));
   c3d.setTriggerCells90percent(percentileTriggerCells(c3d, 0.90));
   c3d.setFirst1layers(sumLayers(c3d, 1, 1));
   c3d.setFirst3layers(sumLayers(c3d, 1, 3));
   c3d.setFirst5layers(sumLayers(c3d, 1, 5));
   c3d.setFirstHcal1layers(sumLayers(c3d, hcal_offset, hcal_offset));
   c3d.setFirstHcal3layers(sumLayers(c3d, hcal_offset, hcal_offset + 2));
   c3d.setFirstHcal5layers(sumLayers(c3d, hcal_offset, hcal_offset + 4));
   c3d.setLast1layers(sumLayers(c3d, lastlayer, lastlayer));
   c3d.setLast3layers(sumLayers(c3d, lastlayer - 2, lastlayer));
   c3d.setLast5layers(sumLayers(c3d, lastlayer - 4, lastlayer));
   c3d.setEmax1layers(sumLayers(c3d, showermaxlayer, showermaxlayer));
   c3d.setEmax3layers(sumLayers(c3d, showermaxlayer - 1, showermaxlayer + 1));
   c3d.setEmax5layers(sumLayers(c3d, showermaxlayer - 2, showermaxlayer + 2));
   c3d.setEot(sumLayers(c3d, 1, hcal_offset));
   c3d.setEbm0(bitmap(c3d, 1, hcal_offset, 0));
   c3d.setEbm1(bitmap(c3d, 1, hcal_offset, 1));
   c3d.setHbm(bitmap(c3d, hcal_offset, lastlayer, 0));
 }

◆ firstLayer()

int HGCalShowerShape::firstLayer ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 30 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), and triggerTools_.

Referenced by fillShapes(), and showerLength().

                                                                       {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   int firstLayer = 999;
 
   for (const auto& id_clu : clustersPtrs) {
     if (!pass(*id_clu.second, c3d))
       continue;
     int layer = triggerTools_.layerWithOffset(id_clu.second->detId());
     if (layer < firstLayer)
       firstLayer = layer;
   }
 
   return firstLayer;
 }

◆ lastLayer()

int HGCalShowerShape::lastLayer ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 65 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), and triggerTools_.

Referenced by showerLength().

                                                                      {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   int lastLayer = -999;
 
   for (const auto& id_clu : clustersPtrs) {
     if (!pass(*id_clu.second, c3d))
       continue;
     int layer = triggerTools_.layerWithOffset(id_clu.second->detId());
     if (layer > lastLayer)
       lastLayer = layer;
   }
 
   return lastLayer;
 }

◆ maxLayer()

int HGCalShowerShape::maxLayer ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 46 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), and triggerTools_.

Referenced by fillShapes().

                                                                     {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   std::unordered_map<int, float> layers_pt;
   float max_pt = 0.;
   int max_layer = 0;
   for (const auto& id_cluster : clustersPtrs) {
     if (!pass(*id_cluster.second, c3d))
       continue;
     unsigned layer = triggerTools_.layerWithOffset(id_cluster.second->detId());
     auto itr_insert = layers_pt.emplace(layer, 0.);
     itr_insert.first->second += id_cluster.second->pt();
     if (itr_insert.first->second > max_pt) {
       max_pt = itr_insert.first->second;
       max_layer = layer;
     }
   }
   return max_layer;
 }

◆ meanX()

float HGCalShowerShape::meanX ( const std::vector< pair< float, float >> & energy_X_tc ) const

private

Definition at line 15 of file HGCalShowerShape.cc.

Referenced by meanZ(), sigmaRRMax(), sigmaRRMean(), sigmaRRTot(), varRR(), and varZZ().

                                                                                     {
   float Etot = 0;
   float X_sum = 0;
 
   for (const auto& energy_X : energy_X_tc) {
     X_sum += energy_X.first * energy_X.second;
     Etot += energy_X.first;
   }
 
   float X_mean = 0;
   if (Etot > 0)
     X_mean = X_sum / Etot;
   return X_mean;
 }

◆ meanZ()

float HGCalShowerShape::meanZ ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 429 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), meanX(), pass(), and caloTruthCellsProducer_cfi::triggerCells.

Referenced by fillShapes().

                                                                    {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_z;
 
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_energy_z.emplace_back(id_tc.second->energy(), id_tc.second->position().z());
     }
   }
 
   return meanX(tc_energy_z);
 }

◆ pass()

template<typename T , typename Tref >

bool HGCalShowerShape::pass	(	const T &	obj,
		const Tref &	ref
	)		const

inlineprivate

Definition at line 99 of file HGCalShowerShape.h.

References funct::abs(), distance_, mag(), getGTfromDQMFile::obj, amptDefault_cfi::proj, and threshold_.

Referenced by bitmap(), coreShowerLength(), eMax(), firstLayer(), lastLayer(), maxLayer(), meanZ(), percentileLayer(), percentileTriggerCells(), sigmaEtaEtaMax(), sigmaEtaEtaTot(), sigmaPhiPhiMax(), sigmaPhiPhiTot(), sigmaRRMax(), sigmaRRMean(), sigmaRRTot(), sumLayers(), varEtaEta(), varPhiPhi(), varRR(), and varZZ().

                                                  {
     bool pass_threshold = (obj.mipPt() > threshold_);
     GlobalPoint proj(Basic3DVector<float>(obj.position()) / std::abs(obj.position().z()));
     bool pass_distance = ((proj - ref.centreProj()).mag() < distance_);
     return pass_threshold && pass_distance;
   }

◆ percentileLayer()

float HGCalShowerShape::percentileLayer	(	const l1t::HGCalMulticluster &	c3d,
		const HGCalTriggerGeometryBase &	triggerGeometry,
		float	quantile = `0.5`
	)		const

Definition at line 112 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), ForwardEmpty, HFNose, HGCalTriggerTools::isNose(), nano_mu_digi_cff::layer, hgcalTBTopologyTester_cfi::layers, HGCalTriggerTools::layers(), pass(), DiDispStaMuonMonitor_cfi::pt, HLT_2024v13_cff::pt1, SusyPostProcessor_cff::quantile, caloTruthCellsProducer_cfi::triggerCells, HGCalTriggerGeometryBase::triggerLayer(), and triggerTools_.

Referenced by fillShapes().

                                                               {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   unsigned nlayers = triggerTools_.layers(ForwardSubdetector::ForwardEmpty);
   std::vector<double> layers(nlayers, 0);
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       unsigned layer = triggerGeometry.triggerLayer(id_tc.second->detId());
       if (triggerTools_.isNose(id_tc.second->detId()))
         nlayers = triggerTools_.layers(ForwardSubdetector::HFNose);
       else {
         nlayers = triggerTools_.layers(ForwardSubdetector::ForwardEmpty);
       }
       if (layer == 0 || layer > nlayers)
         continue;
       layers[layer - 1] += id_tc.second->pt();  //layer 0 doesn't exist, so shift by -1
     }
   }
   std::partial_sum(layers.begin(), layers.end(), layers.begin());
   double pt_threshold = layers.back() * quantile;
   unsigned percentile = 0;
   for (double pt : layers) {
     if (pt > pt_threshold) {
       break;
     }
     percentile++;
   }
   // Linear interpolation of percentile value
   double pt0 = (percentile > 0 ? layers[percentile - 1] : 0.);
   double pt1 = (percentile < layers.size() ? layers[percentile] : layers.back());
   return percentile + (pt1 - pt0 > 0. ? (pt_threshold - pt0) / (pt1 - pt0) : 0.);
 }

◆ percentileTriggerCells()

float HGCalShowerShape::percentileTriggerCells	(	const l1t::HGCalMulticluster &	c3d,
		float	quantile = `0.5`
	)		const

Definition at line 150 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), pass(), SusyPostProcessor_cff::quantile, and caloTruthCellsProducer_cfi::triggerCells.

Referenced by fillShapes().

                                                                                                     {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   std::set<double> ordered_tcs;
   double pt_sum = 0.;
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       ordered_tcs.emplace(id_tc.second->pt());
       pt_sum += id_tc.second->pt();
     }
   }
   double pt_threshold = pt_sum * quantile;
   double partial_sum = 0.;
   double partial_sum_prev = 0.;
   int ntc = 0;
   for (auto itr = ordered_tcs.rbegin(); itr != ordered_tcs.rend(); ++itr) {
     partial_sum_prev = partial_sum;
     partial_sum += *itr;
     ntc++;
     if (partial_sum > pt_threshold) {
       break;
     }
   }
   // Linear interpolation of ntc
   return ntc - 1 +
          (partial_sum - partial_sum_prev > 0. ? (pt_threshold - partial_sum_prev) / (partial_sum - partial_sum_prev)
                                               : 0.);
 }

◆ setGeometry()

void HGCalShowerShape::setGeometry ( const HGCalTriggerGeometryBase *const geom )

inline

Definition at line 21 of file HGCalShowerShape.h.

References relativeConstraints::geom, HGCalTriggerTools::setGeometry(), and triggerTools_.

Referenced by CaloTruthCellsProducer::produce(), HGCalHistoClusteringImpl::setGeometry(), and HGCalMulticlusteringImpl::setGeometry().

21 { triggerTools_.setGeometry(geom); }

HGCalShowerShape::triggerTools_

HGCalTriggerTools triggerTools_

Definition: HGCalShowerShape.h:106

HGCalTriggerTools::setGeometry

void setGeometry(const HGCalTriggerGeometryBase *const)

Definition: HGCalTriggerTools.cc:40

relativeConstraints.geom

geom

Definition: relativeConstraints.py:72

◆ showerLength()

int HGCalShowerShape::showerLength ( const l1t::HGCalMulticluster & c3d ) const

inline

Definition at line 26 of file HGCalShowerShape.h.

References firstLayer(), and lastLayer().

Referenced by fillShapes().

                                                           {
     return lastLayer(c3d) - firstLayer(c3d) + 1;
   }  //in number of layers

◆ sigmaEtaEtaMax()

float HGCalShowerShape::sigmaEtaEtaMax ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 253 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), sigmaXX(), caloTruthCellsProducer_cfi::triggerCells, and triggerTools_.

Referenced by fillShapes().

                                                                             {
   std::unordered_map<int, std::vector<std::pair<float, float>>> tc_layer_energy_eta;
   std::unordered_map<int, LorentzVector> layer_LV;
 
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   for (const auto& id_clu : clustersPtrs) {
     unsigned layer = triggerTools_.layerWithOffset(id_clu.second->detId());
 
     layer_LV[layer] += id_clu.second->p4();
 
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_layer_energy_eta[layer].emplace_back(std::make_pair(id_tc.second->energy(), id_tc.second->eta()));
     }
   }
 
   float SigmaEtaEtaMax = 0;
 
   for (auto& tc_iter : tc_layer_energy_eta) {
     const std::vector<std::pair<float, float>>& energy_eta_layer = tc_iter.second;
     const LorentzVector& LV_layer = layer_LV[tc_iter.first];
     float SigmaEtaEtaLayer = sigmaXX(energy_eta_layer, LV_layer.eta());  //RMS wrt layer eta, not wrt c3d eta
     if (SigmaEtaEtaLayer > SigmaEtaEtaMax)
       SigmaEtaEtaMax = SigmaEtaEtaLayer;
   }
 
   return SigmaEtaEtaMax;
 }

◆ sigmaEtaEtaTot() [1/2]

float HGCalShowerShape::sigmaEtaEtaTot ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 182 of file HGCalShowerShape.cc.

References mathSSE::sqrt(), and varEtaEta().

Referenced by fillShapes().

182 { return sqrt(varEtaEta(c3d)); }

HGCalShowerShape::varEtaEta

float varEtaEta(const l1t::HGCalMulticluster &c3d) const

Definition: HGCalShowerShape.cc:184

mathSSE::sqrt

T sqrt(T t)

Definition: SSEVec.h:23

◆ sigmaEtaEtaTot() [2/2]

float HGCalShowerShape::sigmaEtaEtaTot ( const l1t::HGCalCluster & c2d ) const

Definition at line 468 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), reco::LeafCandidate::eta(), pass(), and sigmaXX().

                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& cellsPtrs = c2d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_eta;
 
   for (const auto& id_cell : cellsPtrs) {
     if (!pass(*id_cell.second, c2d))
       continue;
     tc_energy_eta.emplace_back(std::make_pair(id_cell.second->energy(), id_cell.second->eta()));
   }
 
   float See = sigmaXX(tc_energy_eta, c2d.eta());
 
   return See;
 }

◆ sigmaPhiPhi()

float HGCalShowerShape::sigmaPhiPhi	(	const std::vector< pair< float, float >> &	energy_phi_tc,
		const float	phi_cluster
	)		const

inlineprivate

Definition at line 87 of file HGCalShowerShape.h.

References mathSSE::sqrt(), and varPhiPhi().

Referenced by sigmaPhiPhiMax(), and sigmaPhiPhiTot().

                                                                                                        {
     return sqrt(varPhiPhi(energy_phi_tc, phi_cluster));
   }

◆ sigmaPhiPhiMax()

float HGCalShowerShape::sigmaPhiPhiMax ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 286 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), pass(), sigmaPhiPhi(), caloTruthCellsProducer_cfi::triggerCells, and triggerTools_.

Referenced by fillShapes().

                                                                             {
   std::unordered_map<int, std::vector<std::pair<float, float>>> tc_layer_energy_phi;
   std::unordered_map<int, LorentzVector> layer_LV;
 
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   for (const auto& id_clu : clustersPtrs) {
     unsigned layer = triggerTools_.layerWithOffset(id_clu.second->detId());
 
     layer_LV[layer] += id_clu.second->p4();
 
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_layer_energy_phi[layer].emplace_back(std::make_pair(id_tc.second->energy(), id_tc.second->phi()));
     }
   }
 
   float SigmaPhiPhiMax = 0;
 
   for (auto& tc_iter : tc_layer_energy_phi) {
     const std::vector<std::pair<float, float>>& energy_phi_layer = tc_iter.second;
     const LorentzVector& LV_layer = layer_LV[tc_iter.first];
     float SigmaPhiPhiLayer = sigmaPhiPhi(energy_phi_layer, LV_layer.phi());  //RMS wrt layer phi, not wrt c3d phi
     if (SigmaPhiPhiLayer > SigmaPhiPhiMax)
       SigmaPhiPhiMax = SigmaPhiPhiLayer;
   }
 
   return SigmaPhiPhiMax;
 }

◆ sigmaPhiPhiTot() [1/2]

float HGCalShowerShape::sigmaPhiPhiTot ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 204 of file HGCalShowerShape.cc.

References mathSSE::sqrt(), and varPhiPhi().

Referenced by fillShapes().

204 { return sqrt(varPhiPhi(c3d)); }

mathSSE::sqrt

T sqrt(T t)

Definition: SSEVec.h:23

HGCalShowerShape::varPhiPhi

float varPhiPhi(const l1t::HGCalMulticluster &c3d) const

Definition: HGCalShowerShape.cc:206

◆ sigmaPhiPhiTot() [2/2]

float HGCalShowerShape::sigmaPhiPhiTot ( const l1t::HGCalCluster & c2d ) const

Definition at line 484 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), pass(), reco::LeafCandidate::phi(), and sigmaPhiPhi().

                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& cellsPtrs = c2d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_phi;
 
   for (const auto& id_cell : cellsPtrs) {
     if (!pass(*id_cell.second, c2d))
       continue;
     tc_energy_phi.emplace_back(std::make_pair(id_cell.second->energy(), id_cell.second->phi()));
   }
 
   float Spp = sigmaPhiPhi(tc_energy_phi, c2d.phi());
 
   return Spp;
 }

◆ sigmaRRMax()

float HGCalShowerShape::sigmaRRMax ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 319 of file HGCalShowerShape.cc.

References funct::abs(), l1t::HGCalClusterT< C >::constituents(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), meanX(), pass(), funct::pow(), alignCSCRings::r, sigmaXX(), mathSSE::sqrt(), caloTruthCellsProducer_cfi::triggerCells, and triggerTools_.

Referenced by fillShapes().

                                                                         {
   std::unordered_map<int, std::vector<std::pair<float, float>>> tc_layer_energy_r;
 
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   for (const auto& id_clu : clustersPtrs) {
     unsigned layer = triggerTools_.layerWithOffset(id_clu.second->detId());
 
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       float r = (id_tc.second->position().z() != 0.
                      ? std::sqrt(pow(id_tc.second->position().x(), 2) + pow(id_tc.second->position().y(), 2)) /
                            std::abs(id_tc.second->position().z())
                      : 0.);
       tc_layer_energy_r[layer].emplace_back(std::make_pair(id_tc.second->energy(), r));
     }
   }
 
   float SigmaRRMax = 0;
 
   for (auto& tc_iter : tc_layer_energy_r) {
     const std::vector<std::pair<float, float>>& energy_r_layer = tc_iter.second;
     float r_mean_layer = meanX(energy_r_layer);
     float SigmaRRLayer = sigmaXX(energy_r_layer, r_mean_layer);
     if (SigmaRRLayer > SigmaRRMax)
       SigmaRRMax = SigmaRRLayer;
   }
 
   return SigmaRRMax;
 }

◆ sigmaRRMean()

float HGCalShowerShape::sigmaRRMean	(	const l1t::HGCalMulticluster &	c3d,
		float	radius = `5.`
	)		const

Definition at line 353 of file HGCalShowerShape.cc.

References funct::abs(), l1t::HGCalClusterT< C >::constituents(), PVValHelper::dx, PVValHelper::dy, reco::LeafCandidate::energy(), nano_mu_digi_cff::layer, HGCalTriggerTools::layerWithOffset(), meanX(), pass(), l1t::HGCalTriggerCell::position(), alignCSCRings::r, CosmicsPD_Skims::radius, sigmaXX(), mathSSE::sqrt(), caloTruthCellsProducer_cfi::triggerCells, triggerTools_, PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by fillShapes().

                                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   // group trigger cells by layer
   std::unordered_map<int, std::vector<edm::Ptr<l1t::HGCalTriggerCell>>> layers_tcs;
   for (const auto& id_clu : clustersPtrs) {
     unsigned layer = triggerTools_.layerWithOffset(id_clu.second->detId());
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       layers_tcs[layer].emplace_back(id_tc.second);
     }
   }
 
   // Select trigger cells within X cm of the max TC in the layer
   std::unordered_map<int, std::vector<std::pair<float, float>>> tc_layers_energy_r;
   for (const auto& layer_tcs : layers_tcs) {
     int layer = layer_tcs.first;
     edm::Ptr<l1t::HGCalTriggerCell> max_tc = layer_tcs.second.front();
     for (const auto& tc : layer_tcs.second) {
       if (tc->energy() > max_tc->energy())
         max_tc = tc;
     }
     for (const auto& tc : layer_tcs.second) {
       double dx = tc->position().x() - max_tc->position().x();
       double dy = tc->position().y() - max_tc->position().y();
       double distance_to_max = std::sqrt(dx * dx + dy * dy);
       if (distance_to_max < radius) {
         float r = (tc->position().z() != 0.
                        ? std::sqrt(tc->position().x() * tc->position().x() + tc->position().y() * tc->position().y()) /
                              std::abs(tc->position().z())
                        : 0.);
         tc_layers_energy_r[layer].emplace_back(std::make_pair(tc->energy(), r));
       }
     }
   }
 
   // Compute srr layer by layer
   std::vector<std::pair<float, float>> layers_energy_srr2;
   for (const auto& layer_energy_r : tc_layers_energy_r) {
     const auto& energies_r = layer_energy_r.second;
     float r_mean_layer = meanX(energies_r);
     float srr = sigmaXX(energies_r, r_mean_layer);
     double energy_sum = 0.;
     for (const auto& energy_r : energies_r) {
       energy_sum += energy_r.first;
     }
     layers_energy_srr2.emplace_back(std::make_pair(energy_sum, srr * srr));
   }
   // Combine all layer srr
   float srr2_mean = meanX(layers_energy_srr2);
   return std::sqrt(srr2_mean);
 }

◆ sigmaRRTot() [1/2]

float HGCalShowerShape::sigmaRRTot ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 226 of file HGCalShowerShape.cc.

References mathSSE::sqrt(), and varRR().

Referenced by fillShapes().

226 { return sqrt(varRR(c3d)); }

mathSSE::sqrt

T sqrt(T t)

Definition: SSEVec.h:23

HGCalShowerShape::varRR

float varRR(const l1t::HGCalMulticluster &c3d) const

Definition: HGCalShowerShape.cc:228

◆ sigmaRRTot() [2/2]

float HGCalShowerShape::sigmaRRTot ( const l1t::HGCalCluster & c2d ) const

Definition at line 500 of file HGCalShowerShape.cc.

References funct::abs(), l1t::HGCalClusterT< C >::constituents(), meanX(), pass(), funct::pow(), alignCSCRings::r, sigmaXX(), and mathSSE::sqrt().

                                                                    {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& cellsPtrs = c2d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_r;
 
   for (const auto& id_cell : cellsPtrs) {
     if (!pass(*id_cell.second, c2d))
       continue;
     float r = (id_cell.second->position().z() != 0.
                    ? std::sqrt(pow(id_cell.second->position().x(), 2) + pow(id_cell.second->position().y(), 2)) /
                          std::abs(id_cell.second->position().z())
                    : 0.);
     tc_energy_r.emplace_back(std::make_pair(id_cell.second->energy(), r));
   }
 
   float r_mean = meanX(tc_energy_r);
   float Srr = sigmaXX(tc_energy_r, r_mean);
 
   return Srr;
 }

◆ sigmaXX()

float HGCalShowerShape::sigmaXX	(	const std::vector< pair< float, float >> &	energy_X_tc,
		const float	X_cluster
	)		const

inlineprivate

Definition at line 81 of file HGCalShowerShape.h.

References mathSSE::sqrt(), and varXX().

Referenced by sigmaEtaEtaMax(), sigmaEtaEtaTot(), sigmaRRMax(), sigmaRRMean(), and sigmaRRTot().

                                                                                                {
     float X_RMS = sqrt(varXX(energy_X_tc, X_cluster));
     return X_RMS;
   }

◆ sigmaZZ()

float HGCalShowerShape::sigmaZZ ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 447 of file HGCalShowerShape.cc.

References mathSSE::sqrt(), and varZZ().

Referenced by fillShapes().

447 { return sqrt(varZZ(c3d)); }

HGCalShowerShape::varZZ

float varZZ(const l1t::HGCalMulticluster &c3d) const

Definition: HGCalShowerShape.cc:448

mathSSE::sqrt

T sqrt(T t)

Definition: SSEVec.h:23

◆ sumLayers()

float HGCalShowerShape::sumLayers	(	const l1t::HGCalMulticluster &	c3d,
		int	start = `1`,
		int	end = `0`
	)		const

Definition at line 521 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), mps_fire::end, DivergingColor::frac, HGCalTriggerTools::getTriggerGeometry(), mps_fire::i, HGCalTriggerGeometryBase::lastTriggerLayer(), nano_mu_digi_cff::layer, hgcalTBTopologyTester_cfi::layers, pass(), compareTotals::tot, caloTruthCellsProducer_cfi::triggerCells, HGCalTriggerTools::triggerLayer(), and triggerTools_.

Referenced by fillShapes().

                                                                                            {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
   unsigned nlayers = triggerTools_.getTriggerGeometry()->lastTriggerLayer();
   std::vector<double> layers(nlayers, 0);
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       unsigned layer = triggerTools_.triggerLayer(id_tc.second->detId());
       if (layer == 0 || layer > nlayers)
         continue;
       layers[layer - 1] += id_tc.second->pt();  //shift by -1 because layer 0 doesn't exist
     }
   }
   double sum_pt = 0;
   for (int i = start - 1; i <= end - 1; i++) {  //shift by -1 because layer 1 is layers[0]
     sum_pt += layers[i];
   }
   double tot = 0;
   for (unsigned i = 0; i < layers.size(); ++i) {
     tot += layers[i];
   }
   float frac = 0;
   if (tot > 0) {
     frac = sum_pt / tot;
   }
   return frac;
 }

◆ varEtaEta()

float HGCalShowerShape::varEtaEta ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 184 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), reco::LeafCandidate::eta(), pass(), caloTruthCellsProducer_cfi::triggerCells, and varXX().

Referenced by fillShapes(), and sigmaEtaEtaTot().

                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_eta;
 
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_energy_eta.emplace_back(std::make_pair(id_tc.second->energy(), id_tc.second->eta()));
     }
   }
 
   float varee = varXX(tc_energy_eta, c3d.eta());
 
   return varee;
 }

◆ varPhiPhi() [1/2]

float HGCalShowerShape::varPhiPhi ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 206 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), pass(), reco::LeafCandidate::phi(), and caloTruthCellsProducer_cfi::triggerCells.

Referenced by fillShapes(), sigmaPhiPhi(), and sigmaPhiPhiTot().

                                                                        {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_phi;
 
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_energy_phi.emplace_back(std::make_pair(id_tc.second->energy(), id_tc.second->phi()));
     }
   }
 
   float varphiphi = varPhiPhi(tc_energy_phi, c3d.phi());
 
   return varphiphi;
 }

◆ varPhiPhi() [2/2]

float HGCalShowerShape::varPhiPhi	(	const std::vector< pair< float, float >> &	energy_phi_tc,
		const float	phi_cluster
	)		const

inlineprivate

Definition at line 94 of file HGCalShowerShape.h.

                                                                                                      {
     return varXX<DeltaPhi<float>>(energy_phi_tc, phi_cluster);
   }

◆ varRR()

float HGCalShowerShape::varRR ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 228 of file HGCalShowerShape.cc.

References funct::abs(), l1t::HGCalClusterT< C >::constituents(), meanX(), pass(), funct::pow(), alignCSCRings::r, mathSSE::sqrt(), caloTruthCellsProducer_cfi::triggerCells, and varXX().

Referenced by fillShapes(), and sigmaRRTot().

                                                                    {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_r;
 
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       float r = (id_tc.second->position().z() != 0.
                      ? std::sqrt(pow(id_tc.second->position().x(), 2) + pow(id_tc.second->position().y(), 2)) /
                            std::abs(id_tc.second->position().z())
                      : 0.);
       tc_energy_r.emplace_back(std::make_pair(id_tc.second->energy(), r));
     }
   }
 
   float r_mean = meanX(tc_energy_r);
   float vrr = varXX(tc_energy_r, r_mean);
 
   return vrr;
 }

◆ varXX()

template<typename Delta = std::minus<float>>

float HGCalShowerShape::varXX	(	const std::vector< pair< float, float >> &	energy_X_tc,
		const float	X_cluster
	)		const

inlineprivate

Definition at line 67 of file HGCalShowerShape.h.

References dumpMFGeometry_cfg::delta, and funct::pow().

Referenced by sigmaXX(), varEtaEta(), varRR(), and varZZ().

                                                                                              {
     Delta delta;
     float Etot = 0;
     float deltaX2_sum = 0;
     for (const auto& energy_X : energy_X_tc) {
       deltaX2_sum += energy_X.first * pow(delta(energy_X.second, X_cluster), 2);
       Etot += energy_X.first;
     }
     float X_MSE = 0;
     if (Etot > 0)
       X_MSE = deltaX2_sum / Etot;
     return X_MSE;
   }

◆ varZZ()

float HGCalShowerShape::varZZ ( const l1t::HGCalMulticluster & c3d ) const

Definition at line 448 of file HGCalShowerShape.cc.

References l1t::HGCalClusterT< C >::constituents(), meanX(), pass(), caloTruthCellsProducer_cfi::triggerCells, and varXX().

Referenced by fillShapes(), and sigmaZZ().

                                                                    {
   const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalCluster>>& clustersPtrs = c3d.constituents();
 
   std::vector<std::pair<float, float>> tc_energy_z;
 
   for (const auto& id_clu : clustersPtrs) {
     const std::unordered_map<uint32_t, edm::Ptr<l1t::HGCalTriggerCell>>& triggerCells = id_clu.second->constituents();
 
     for (const auto& id_tc : triggerCells) {
       if (!pass(*id_tc.second, c3d))
         continue;
       tc_energy_z.emplace_back(std::make_pair(id_tc.second->energy(), id_tc.second->position().z()));
     }
   }
 
   float z_mean = meanX(tc_energy_z);
   float varzz = varXX(tc_energy_z, z_mean);
 
   return varzz;
 }

Member Data Documentation

◆ distance_

double HGCalShowerShape::distance_ = 1.

private

Definition at line 108 of file HGCalShowerShape.h.

Referenced by pass().

◆ threshold_

double HGCalShowerShape::threshold_ = 0.

private

Definition at line 107 of file HGCalShowerShape.h.

Referenced by pass().

◆ triggerTools_

HGCalTriggerTools HGCalShowerShape::triggerTools_

private

Definition at line 106 of file HGCalShowerShape.h.

Referenced by bitmap(), coreShowerLength(), eMax(), fillShapes(), firstLayer(), lastLayer(), maxLayer(), percentileLayer(), setGeometry(), sigmaEtaEtaMax(), sigmaPhiPhiMax(), sigmaRRMax(), sigmaRRMean(), and sumLayers().

Classes

Public Types

Public Member Functions

Private Member Functions

Private Attributes

Detailed Description

Member Typedef Documentation

◆ LorentzVector

Constructor & Destructor Documentation

◆ HGCalShowerShape() [1/2]

◆ HGCalShowerShape() [2/2]

◆ ~HGCalShowerShape()

Member Function Documentation

◆ bitmap()

◆ coreShowerLength()

◆ eMax()

◆ fillShapes()

◆ firstLayer()

◆ lastLayer()

◆ maxLayer()

◆ meanX()

◆ meanZ()

◆ pass()

◆ percentileLayer()

◆ percentileTriggerCells()

◆ setGeometry()

◆ showerLength()

◆ sigmaEtaEtaMax()

◆ sigmaEtaEtaTot() [1/2]

◆ sigmaEtaEtaTot() [2/2]

◆ sigmaPhiPhi()

◆ sigmaPhiPhiMax()

◆ sigmaPhiPhiTot() [1/2]

◆ sigmaPhiPhiTot() [2/2]

◆ sigmaRRMax()

◆ sigmaRRMean()

◆ sigmaRRTot() [1/2]

◆ sigmaRRTot() [2/2]

◆ sigmaXX()

◆ sigmaZZ()

◆ sumLayers()

◆ varEtaEta()

◆ varPhiPhi() [1/2]

◆ varPhiPhi() [2/2]

◆ varRR()

◆ varXX()

◆ varZZ()

Member Data Documentation

◆ distance_

◆ threshold_

◆ triggerTools_