SiStripCalibLorentzAngle Class Reference

#include <SiStripCalibLorentzAngle.h>

Inheritance diagram for SiStripCalibLorentzAngle:

Public Member Functions
void	algoBeginJob (const edm::EventSetup &) override
std::unique_ptr< SiStripLorentzAngle >	getNewObject () override
	SiStripCalibLorentzAngle (const edm::ParameterSet &conf)
	~SiStripCalibLorentzAngle () override
Public Member Functions inherited from ConditionDBWriter< SiStripLorentzAngle >
	ConditionDBWriter (const edm::ParameterSet &iConfig)
	~ConditionDBWriter () override
Public Member Functions inherited from edm::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzer ()
SerialTaskQueue *	globalLuminosityBlocksQueue ()
SerialTaskQueue *	globalRunsQueue ()
ModuleDescription const &	moduleDescription () const
std::string	workerType () const
	~EDAnalyzer () 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
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::vector< ModuleDescription const * > &modules, 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
ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const
void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)
virtual	~EDConsumerBase () noexcept(false)

Private Types
typedef std::map< std::string, TProfile * >	ProfileMap
typedef std::map< std::string, TH1D * >	TH1Dmap
typedef std::map< std::string, TH2D * >	TH2Dmap

Private Attributes
float	AsymmParam
int	badFit
bool	CalibByMC
edm::ParameterSet	conf_
std::map< uint32_t, float >	detid_la
edm::ESHandle< TrackerGeometry >	estracker
TDirectory *	FirstIT_GoodFit_Histos
TF1 *	fitfunc
TF1 *	fitfunc2IT
TF1 *	FitFunction
TF1 *	FitFunction2IT
float	geta
float	globalX
float	globalY
float	globalZ
int	goodFit
int	goodFit1IT
float	gphi
const GlobalPoint	gposition
float	gR
float	gz
float	hallMobility
TFile *	hFile
float	histoEntries
std::vector< MonitorElement * >	histolist
int	Layer
bool	LayerDB
TDirectory *	LorentzAngle_Plots
edm::ESHandle< MagneticField >	magfield_
float	mean_TIB1
float	mean_TIB2
float	mean_TIB3
float	mean_TIB4
float	mean_TOB1
float	mean_TOB2
float	mean_TOB3
float	mean_TOB4
float	mean_TOB5
float	mean_TOB6
float	meanMobility_TIB
float	meanMobility_TOB
TTree *	ModuleTree
int	MonoStereo
float	muH
TDirectory *	MuH
TDirectory *	MuH_vs_Eta
TDirectory *	MuH_vs_Phi
ProfileMap	Profiles
TDirectory *	Rootple
TDirectory *	SecondIT_BadFit_Histos
TDirectory *	SecondIT_GoodFit_Histos
TH1Dmap	TH1Ds
TH2Dmap	TH2Ds
float	theBfield
int	TIB
TDirectory *	TIB_1IT_GoodFit
TDirectory *	TIB_2IT_BadFit
TDirectory *	TIB_2IT_GoodFit
TDirectory *	TIB_Eta
TGraphErrors *	TIB_graph
TDirectory *	TIB_MuH
TDirectory *	TIB_Phi
int	TOB
TDirectory *	TOB_1IT_GoodFit
TDirectory *	TOB_2IT_BadFit
TDirectory *	TOB_2IT_GoodFit
TDirectory *	TOB_Eta
TGraphErrors *	TOB_graph
TDirectory *	TOB_MuH
TDirectory *	TOB_Phi
const TrackerGeometry *	tracker
const TrackerTopology *	tTopo

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &)
static bool	wantsGlobalLuminosityBlocks ()
static bool	wantsGlobalRuns ()
static bool	wantsStreamLuminosityBlocks ()
static bool	wantsStreamRuns ()
Protected Member Functions inherited from ConditionDBWriter< SiStripLorentzAngle >
void	setDoStore (const bool doStore)
	When set to false the payload will not be written to the db. More...
void	storeOnDbNow ()
cond::Time_t	timeOfLastIOV ()
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
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<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)

Detailed Description

Definition at line 38 of file SiStripCalibLorentzAngle.h.

Member Typedef Documentation

typedef std::map<std::string , TProfile*> SiStripCalibLorentzAngle::ProfileMap

private

Definition at line 58 of file SiStripCalibLorentzAngle.h.

typedef std::map<std::string , TH1D*> SiStripCalibLorentzAngle::TH1Dmap

private

Definition at line 60 of file SiStripCalibLorentzAngle.h.

typedef std::map<std::string , TH2D*> SiStripCalibLorentzAngle::TH2Dmap

private

Definition at line 62 of file SiStripCalibLorentzAngle.h.

Constructor & Destructor Documentation

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

explicit

Definition at line 22 of file SiStripCalibLorentzAngle.cc.

: ConditionDBWriter<SiStripLorentzAngle>(conf) , tTopo(nullptr), conf_(conf) {}

SiStripCalibLorentzAngle::~SiStripCalibLorentzAngle ( )

override

Definition at line 762 of file SiStripCalibLorentzAngle.cc.

References hFile.

                                                   {
 delete hFile;
}

Member Function Documentation

void SiStripCalibLorentzAngle::algoBeginJob ( const edm::EventSetup &  c )

overridevirtual

Reimplemented from ConditionDBWriter< SiStripLorentzAngle >.

Definition at line 24 of file SiStripCalibLorentzAngle.cc.

References badFit, Surface::bounds(), CalibByMC, conf_, dbe_, detid_la, estracker, PV3DBase< T, PVType, FrameType >::eta(), extract(), FirstIT_GoodFit_Histos, fitfunc, fitfunc2IT, FitFunction, FitFunction2IT, edm::EventSetup::get(), geta, DQMStore::getAllContents(), SiStripHistoId::getComponentId(), SiStripLorentzAngle::getLorentzAngles(), edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), globalX, globalY, globalZ, goodFit, goodFit1IT, gphi, gposition, gR, gz, hFile, trackerHits::histo, histoEntries, histolist, triggerObjects_cff::id, TrackerGeometry::idToDetUnit(), createfilelist::int, MagneticField::inTesla(), Layer, LayerDB, StripTopology::localPitch(), LorentzAngle_Plots, PV3DBase< T, PVType, FrameType >::mag(), magfield_, mean_TIB1, mean_TIB2, mean_TIB3, mean_TIB4, mean_TOB1, mean_TOB2, mean_TOB3, mean_TOB4, mean_TOB5, mean_TOB6, meanMobility_TIB, meanMobility_TOB, ModuleTree, MonoStereo, muH, MuH, MuH_vs_Eta, MuH_vs_Phi, dataset::name, DQMStore::open(), Utilities::operator, AlCaHLTBitMon_ParallelJobs::p, PV3DBase< T, PVType, FrameType >::phi(), GloballyPositioned< T >::position(), funct::pow(), edm::ESHandle< T >::product(), Profiles, Rootple, SecondIT_BadFit_Histos, SecondIT_GoodFit_Histos, GeomDet::specificSurface(), mathSSE::sqrt(), StripSubdetector::stereo(), AlCaHLTBitMon_QueryRunRegistry::string, DetId::subdetId(), GeomDet::surface(), TH1Ds, TH2Ds, theBfield, Bounds::thickness(), StripSubdetector::TIB, TIB, TIB_1IT_GoodFit, TIB_2IT_BadFit, TIB_2IT_GoodFit, TIB_Eta, TIB_graph, TIB_MuH, TIB_Phi, TrackerTopology::tibLayer(), StripSubdetector::TOB, TOB, TOB_1IT_GoodFit, TOB_2IT_BadFit, TOB_2IT_GoodFit, TOB_Eta, TOB_graph, TOB_MuH, TOB_Phi, TrackerTopology::tobLayer(), toLocal(), GeomDet::topology(), tracker, tTopo, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

                                                                 {
  //Retrieve tracker topology from geometry
  edm::ESHandle<TrackerTopology> tTopoHandle;
  c.get<TrackerTopologyRcd>().get(tTopoHandle);
  tTopo = tTopoHandle.product();

  c.get<TrackerDigiGeometryRecord>().get(estracker);
  tracker=&(*estracker); 
  
  //get magnetic field and geometry from ES
  edm::ESHandle<MagneticField> magfield_;
  c.get<IdealMagneticFieldRecord>().get(magfield_);

  edm::ESHandle<SiStripLorentzAngle> SiStripLorentzAngle_;
  c.get<SiStripLorentzAngleRcd>().get(SiStripLorentzAngle_);
  detid_la= SiStripLorentzAngle_->getLorentzAngles();
  
  DQMStore* dbe_ = edm::Service<DQMStore>().operator->();
  
  std::string inputFile_ =conf_.getUntrackedParameter<std::string>("fileName", "LAProfiles.root");
  std::string LAreport_ =conf_.getUntrackedParameter<std::string>("LA_Report", "LA_Report.txt");
  std::string NoEntriesHisto_ =conf_.getUntrackedParameter<std::string>("NoEntriesHisto", "NoEntriesHisto.txt");
  std::string Dir_Name_ =conf_.getUntrackedParameter<std::string>("Dir_Name", "SiStrip");
  
  LayerDB = conf_.getUntrackedParameter<bool>("LayerDB", false);
  
  CalibByMC = conf_.getUntrackedParameter<bool>("CalibByMC", false);
  
  dbe_->open(inputFile_);
  
  // use SistripHistoId for producing histogram id (and title)
  SiStripHistoId hidmanager;
  
  edm::LogInfo("SiStripCalibLorentzAngle")<<"### DIR-NAME = "<<Dir_Name_;
  histolist= dbe_->getAllContents(Dir_Name_);
  std::vector<MonitorElement*>::iterator histo;
  
  hFile = new TFile (conf_.getUntrackedParameter<std::string>("out_fileName").c_str(), "RECREATE" );
    
  LorentzAngle_Plots = hFile->mkdir("LorentzAngle_Plots");
  Rootple = LorentzAngle_Plots->mkdir("Rootple");
  MuH = LorentzAngle_Plots->mkdir("MuH");
  TIB_MuH = MuH->mkdir("TIB_MuH");
  TOB_MuH = MuH->mkdir("TOB_MuH");
  MuH_vs_Phi = LorentzAngle_Plots->mkdir("MuH_vs_Phi");
  TIB_Phi = MuH_vs_Phi->mkdir("TIB_Phi");
  TOB_Phi = MuH_vs_Phi->mkdir("TOB_Phi");
  MuH_vs_Eta = LorentzAngle_Plots->mkdir("MuH_vs_Eta");
  TIB_Eta = MuH_vs_Eta->mkdir("TIB_Eta");
  TOB_Eta = MuH_vs_Eta->mkdir("TOB_Eta");
  FirstIT_GoodFit_Histos = LorentzAngle_Plots->mkdir("1IT_GoodFit_Histos");
  TIB_1IT_GoodFit = FirstIT_GoodFit_Histos->mkdir("TIB_1IT_GoodFit");
  TOB_1IT_GoodFit = FirstIT_GoodFit_Histos->mkdir("TOB_1IT_GoodFit");
  SecondIT_GoodFit_Histos = LorentzAngle_Plots->mkdir("2IT_GoodFit_Histos");
  TIB_2IT_GoodFit = SecondIT_GoodFit_Histos->mkdir("TIB_2IT_GoodFit");
  TOB_2IT_GoodFit = SecondIT_GoodFit_Histos->mkdir("TOB_2IT_GoodFit");
  SecondIT_BadFit_Histos = LorentzAngle_Plots->mkdir("2IT_BadFit_Histos");
  TIB_2IT_BadFit = SecondIT_BadFit_Histos->mkdir("TIB_2IT_BadFit");
  TOB_2IT_BadFit = SecondIT_BadFit_Histos->mkdir("TOB_2IT_BadFit");
    
  TH1Ds["LA_TIB"] = new TH1D("TanLAPerTesla TIB","TanLAPerTesla TIB",1000,-0.5,0.5);
  TH1Ds["LA_TIB"]->SetDirectory(MuH);
  TH1Ds["LA_TOB"] = new TH1D("TanLAPerTesla TOB","TanLAPerTesla TOB",1000,-0.5,0.5);
  TH1Ds["LA_TOB"]->SetDirectory(MuH);
  TH1Ds["LA_err_TIB"] = new TH1D("TanLAPerTesla Error TIB","TanLAPerTesla Error TIB",1000,0,1);
  TH1Ds["LA_err_TIB"]->SetDirectory(MuH);
  TH1Ds["LA_err_TOB"] = new TH1D("TanLAPerTesla Error TOB","TanLAPerTesla Error TOB",1000,0,1);
  TH1Ds["LA_err_TOB"]->SetDirectory(MuH);
  TH1Ds["LA_chi2norm_TIB"] = new TH1D("TanLAPerTesla Chi2norm TIB","TanLAPerTesla Chi2norm TIB",2000,0,10);
  TH1Ds["LA_chi2norm_TIB"]->SetDirectory(MuH);
  TH1Ds["LA_chi2norm_TOB"] = new TH1D("TanLAPerTesla Chi2norm TOB","TanLAPerTesla Chi2norm TOB",2000,0,10);
  TH1Ds["LA_chi2norm_TOB"]->SetDirectory(MuH);
  TH1Ds["MagneticField"] = new TH1D("MagneticField","MagneticField",500,0,5);
  TH1Ds["MagneticField"]->SetDirectory(MuH);
  
  TH2Ds["LA_TIB_graph"] = new TH2D("TanLAPerTesla TIB Layers","TanLAPerTesla TIB Layers",60,0,5,1000,-0.3,0.3);
  TH2Ds["LA_TIB_graph"]->SetDirectory(MuH);
  TH2Ds["LA_TIB_graph"]->SetNdivisions(6);
  TH2Ds["LA_TOB_graph"] = new TH2D("TanLAPerTesla TOB Layers","TanLAPerTesla TOB Layers",80,0,7,1000,-0.3,0.3);
  TH2Ds["LA_TOB_graph"]->SetDirectory(MuH);
  TH2Ds["LA_TOB_graph"]->SetNdivisions(8);

  TH1Ds["LA_TIB_1"] = new TH1D("TanLAPerTesla TIB1","TanLAPerTesla TIB1",2000,-0.5,0.5);
  TH1Ds["LA_TIB_1"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_1_mono"] = new TH1D("TanLAPerTesla TIB1 MONO","TanLAPerTesla TIB1 MONO",2000,-0.5,0.5);
  TH1Ds["LA_TIB_1_mono"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_1_stereo"] = new TH1D("TanLAPerTesla TIB1 STEREO","TanLAPerTesla TIB1 STEREO",2000,-0.5,0.5);
  TH1Ds["LA_TIB_1_stereo"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_2"] = new TH1D("TanLAPerTesla TIB2","TanLAPerTesla TIB2",2000,-0.5,0.5);
  TH1Ds["LA_TIB_2"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_2_mono"] = new TH1D("TanLAPerTesla TIB2 MONO","TanLAPerTesla TIB2 MONO",2000,-0.5,0.5);
  TH1Ds["LA_TIB_2_mono"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_2_stereo"] = new TH1D("TanLAPerTesla TIB2 STEREO","TanLAPerTesla TIB2 STEREO",2000,-0.5,0.5);
  TH1Ds["LA_TIB_2_stereo"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_3"] = new TH1D("TanLAPerTesla_TIB 3","TanLAPerTesla TIB3",2000,-0.5,0.5);
  TH1Ds["LA_TIB_3"]->SetDirectory(TIB_MuH);
  TH1Ds["LA_TIB_4"] = new TH1D("TanLAPerTesla_TIB 4","TanLAPerTesla TIB4",2000,-0.5,0.5);
  TH1Ds["LA_TIB_4"]->SetDirectory(TIB_MuH);
  
  TH1Ds["LA_TOB_1"] = new TH1D("TanLAPerTesla TOB1","TanLAPerTesla TOB1",2000,-0.5,0.5);
  TH1Ds["LA_TOB_1"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_1_mono"] = new TH1D("TanLAPerTesla TOB1 MONO","TanLAPerTesla TOB1 MONO",2000,-0.5,0.5);
  TH1Ds["LA_TOB_1_mono"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_1_stereo"] = new TH1D("TanLAPerTesla TOB1 STEREO","TanLAPerTesla TOB1 STEREO",2000,-0.5,0.5);
  TH1Ds["LA_TOB_1_stereo"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_2"] = new TH1D("TanLAPerTesla TOB2","TanLAPerTesla TOB2",2000,-0.5,0.5);
  TH1Ds["LA_TOB_2"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_2_mono"] = new TH1D("TanLAPerTesla TOB2 MONO","TanLAPerTesla TOB2 MONO",2000,-0.5,0.5);
  TH1Ds["LA_TOB_2_mono"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_2_stereo"] = new TH1D("TanLAPerTesla TOB2 STEREO","TanLAPerTesla TOB2 STEREO",2000,-0.5,0.5);
  TH1Ds["LA_TOB_2_stereo"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_3"] = new TH1D("TanLAPerTesla TOB3","TanLAPerTesla TOB3",2000,-0.5,0.5);
  TH1Ds["LA_TOB_3"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_4"] = new TH1D("TanLAPerTesla TOB4","TanLAPerTesla TOB4",2000,-0.5,0.5);
  TH1Ds["LA_TOB_4"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_5"] = new TH1D("TanLAPerTesla TOB5","TanLAPerTesla TOB5",2000,-0.5,0.5);
  TH1Ds["LA_TOB_5"]->SetDirectory(TOB_MuH);
  TH1Ds["LA_TOB_6"] = new TH1D("TanLAPerTesla TOB6","TanLAPerTesla TOB6",2000,-0.5,0.5); 
  TH1Ds["LA_TOB_6"]->SetDirectory(TOB_MuH);
    
  TH2Ds["LA_phi_TIB"] = new TH2D("TanLAPerTesla vs Phi TIB","TanLAPerTesla vs Phi TIB",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB"]->SetDirectory(MuH_vs_Phi);
  TH2Ds["LA_phi_TOB"] = new TH2D("TanLAPerTesla vs Phi TOB","TanLAPerTesla vs Phi TOB",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB"]->SetDirectory(MuH_vs_Phi);
  
  TH2Ds["LA_phi_TIB1"] = new TH2D("TanLAPerTesla vs Phi TIB1","TanLAPerTesla vs Phi TIB1",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB1"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB1_mono"] = new TH2D("TanLAPerTesla vs Phi TIB1 MONO","TanLAPerTesla vs Phi TIB1 MONO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB1_mono"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB1_stereo"] = new TH2D("TanLAPerTesla vs Phi TIB1 STEREO","TanLAPerTesla vs Phi TIB1 STEREO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB1_stereo"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB2"] = new TH2D("TanLAPerTesla vs Phi TIB2","TanLAPerTesla vs Phi TIB2",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB2"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB2_mono"] = new TH2D("TanLAPerTesla vs Phi TIB2 MONO","TanLAPerTesla vs Phi TIB2 MONO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB2_mono"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB2_stereo"] = new TH2D("TanLAPerTesla vs Phi TIB2 STEREO","TanLAPerTesla vs Phi TIB2 STEREO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB2_stereo"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB3"] = new TH2D("TanLAPerTesla vs Phi TIB3","TanLAPerTesla vs Phi TIB3",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB3"]->SetDirectory(TIB_Phi);
  TH2Ds["LA_phi_TIB4"] = new TH2D("TanLAPerTesla vs Phi TIB4","TanLAPerTesla vs Phi TIB4",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TIB4"]->SetDirectory(TIB_Phi);
  
  TH2Ds["LA_phi_TOB1"] = new TH2D("TanLAPerTesla vs Phi TOB1","TanLAPerTesla vs Phi TOB1",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB1"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB1_mono"] = new TH2D("TanLAPerTesla vs Phi TOB1 MONO","TanLAPerTesla vs Phi TOB1 MONO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB1_mono"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB1_stereo"] = new TH2D("TanLAPerTesla vs Phi TOB1 STEREO","TanLAPerTesla vs Phi TOB1 STEREO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB1_stereo"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB2"] = new TH2D("TanLAPerTesla vs Phi TOB2","TanLAPerTesla vs Phi TOB2",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB2"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB2_mono"] = new TH2D("TanLAPerTesla vs Phi TOB2 MONO","TanLAPerTesla vs Phi TOB2 MONO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB2_mono"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB2_stereo"] = new TH2D("TanLAPerTesla vs Phi TOB2 STEREO","TanLAPerTesla vs Phi TOB2 STEREO",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB2_stereo"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB3"] = new TH2D("TanLAPerTesla vs Phi TOB3","TanLAPerTesla vs Phi TOB3",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB3"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB4"] = new TH2D("TanLAPerTesla vs Phi TOB4","TanLAPerTesla vs Phi TOB4",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB4"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB5"] = new TH2D("TanLAPerTesla vs Phi TOB5","TanLAPerTesla vs Phi TOB5",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB5"]->SetDirectory(TOB_Phi);
  TH2Ds["LA_phi_TOB6"] = new TH2D("TanLAPerTesla vs Phi TOB6","TanLAPerTesla vs Phi TOB6",800,-4,4,600,-0.3,0.3);
  TH2Ds["LA_phi_TOB6"]->SetDirectory(TOB_Phi);
  
  TH2Ds["LA_eta_TIB"] = new TH2D("TanLAPerTesla vs Eta TIB","TanLAPerTesla vs Eta TIB",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB"]->SetDirectory(MuH_vs_Eta);
  TH2Ds["LA_eta_TOB"] = new TH2D("TanLAPerTesla vs Eta TOB","TanLAPerTesla vs Eta TOB",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB"]->SetDirectory(MuH_vs_Eta);
  
  TH2Ds["LA_eta_TIB1"] = new TH2D("TanLAPerTesla vs Eta TIB1","TanLAPerTesla vs Eta TIB1",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB1"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB1_mono"] = new TH2D("TanLAPerTesla vs Eta TIB1 MONO","TanLAPerTesla vs Eta TIB1 MONO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB1_mono"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB1_stereo"] = new TH2D("TanLAPerTesla vs Eta TIB1 STEREO","TanLAPerTesla vs Eta TIB1 STEREO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB1_stereo"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB2"] = new TH2D("TanLAPerTesla vs Eta TIB2","TanLAPerTesla vs Eta TIB2",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB2"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB2_mono"] = new TH2D("TanLAPerTesla vs Eta TIB2 MONO","TanLAPerTesla vs Eta TIB2 MONO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB2_mono"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB2_stereo"] = new TH2D("TanLAPerTesla vs Eta TIB2 STEREO","TanLAPerTesla vs Eta TIB2 STEREO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB2_stereo"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB3"] = new TH2D("TanLAPerTesla vs Eta TIB3","TanLAPerTesla vs Eta TIB3",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB3"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TIB4"] = new TH2D("TanLAPerTesla vs Eta TIB4","TanLAPerTesla vs Eta TIB4",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TIB4"]->SetDirectory(TIB_Eta);
  
  TH2Ds["LA_eta_TOB1"] = new TH2D("TanLAPerTesla vs Eta TOB1","TanLAPerTesla vs Eta TOB1",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB1"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB1_mono"] = new TH2D("TanLAPerTesla vs Eta TOB1 MONO","TanLAPerTesla vs Eta TOB1 MONO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB1_mono"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB1_stereo"] = new TH2D("TanLAPerTesla vs Eta TOB1 STEREO","TanLAPerTesla vs Eta TOB1 STEREO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB1_stereo"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB2"] = new TH2D("TanLAPerTesla vs Eta TOB2","TanLAPerTesla vs Eta TOB2",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB2"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB2_mono"] = new TH2D("TanLAPerTesla vs Eta TOB2 MONO","TanLAPerTesla vs Eta TOB2 MONO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB2_mono"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB2_stereo"] = new TH2D("TanLAPerTesla vs Eta TOB2 STEREO","TanLAPerTesla vs Eta TOB2 STEREO",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB2_stereo"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB3"] = new TH2D("TanLAPerTesla vs Eta TOB3","TanLAPerTesla vs Eta TOB3",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB3"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB4"] = new TH2D("TanLAPerTesla vs Eta TOB4","TanLAPerTesla vs Eta TOB4",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB4"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB5"] = new TH2D("TanLAPerTesla vs Eta TOB5","TanLAPerTesla vs Eta TOB5",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB5"]->SetDirectory(TIB_Eta);
  TH2Ds["LA_eta_TOB6"] = new TH2D("TanLAPerTesla vs Eta TOB6","TanLAPerTesla vs Eta TOB6",800,-2.6,2.6,600,-0.3,0.3);
  TH2Ds["LA_eta_TOB6"]->SetDirectory(TIB_Eta);
  
  ModuleTree = new TTree("ModuleTree", "ModuleTree");
  ModuleTree->Branch("histoEntries", &histoEntries, "histoEntries/F");
  ModuleTree->Branch("globalX", &globalX, "globalX/F");
  ModuleTree->Branch("globalY", &globalY, "globalY/F");
  ModuleTree->Branch("globalZ", &globalZ, "globalZ/F");
  ModuleTree->Branch("gphi", &gphi, "gphi/F");
  ModuleTree->Branch("geta", &geta, "geta/F");
  ModuleTree->Branch("gR", &gR, "gR/F");
  ModuleTree->Branch("goodFit", &goodFit, "goodFit/I");
  ModuleTree->Branch("goodFit1IT", &goodFit1IT, "goodFit1IT/I");
  ModuleTree->Branch("badFit", &badFit, "badFit/I");
  ModuleTree->Branch("TIB", &TIB, "TIB/I");
  ModuleTree->Branch("TOB", &TOB, "TOB/I");
  ModuleTree->Branch("Layer", &Layer, "Layer/I");
  ModuleTree->Branch("MonoStereo", &MonoStereo, "MonoStereo/I");
  ModuleTree->Branch("theBfield", &theBfield, "theBfield/F");
  ModuleTree->Branch("muH", &muH, "muH/F");
  
  ModuleTree->SetDirectory(Rootple);
     
  int histocounter = 0;
  int NotEnoughEntries = 0;
  int ZeroEntries = 0;
  int GoodFit = 0;
  int FirstIT_goodfit = 0;
  int FirstIT_badfit = 0;
  int SecondIT_badfit = 0;
  int SecondIT_goodfit = 0;
  int no_mod_histo = 0;
  float chi2norm = 0;
  LocalPoint p =LocalPoint(0,0,0);
  
  double ModuleRangeMin=conf_.getParameter<double>("ModuleFitXMin");
  double ModuleRangeMax=conf_.getParameter<double>("ModuleFitXMax");
  double ModuleRangeMin2IT=conf_.getParameter<double>("ModuleFit2ITXMin");
  double ModuleRangeMax2IT=conf_.getParameter<double>("ModuleFit2ITXMax");
  double FitCuts_Entries=conf_.getParameter<double>("FitCuts_Entries");
  double FitCuts_p0=conf_.getParameter<double>("FitCuts_p0");
  double FitCuts_p1=conf_.getParameter<double>("FitCuts_p1");
  double FitCuts_p2=conf_.getParameter<double>("FitCuts_p2");
  double FitCuts_chi2=conf_.getParameter<double>("FitCuts_chi2");
  double FitCuts_ParErr_p0=conf_.getParameter<double>("FitCuts_ParErr_p0");
  double p0_guess=conf_.getParameter<double>("p0_guess");
  double p1_guess=conf_.getParameter<double>("p1_guess");
  double p2_guess=conf_.getParameter<double>("p2_guess");
  
  double TIB1calib = 1.;
  double TIB2calib = 1.;
  double TIB3calib = 1.;
  double TIB4calib = 1.;
  double TOB1calib = 1.;
  double TOB2calib = 1.;
  double TOB3calib = 1.;
  double TOB4calib = 1.;
  double TOB5calib = 1.;
  double TOB6calib = 1.;
  
  if(CalibByMC==true){
  //Calibration factors evaluated by using MC analysis
  TIB1calib=conf_.getParameter<double>("TIB1calib");
  TIB2calib=conf_.getParameter<double>("TIB2calib");
  TIB3calib=conf_.getParameter<double>("TIB3calib");
  TIB4calib=conf_.getParameter<double>("TIB4calib");
  TOB1calib=conf_.getParameter<double>("TOB1calib");
  TOB2calib=conf_.getParameter<double>("TOB2calib");
  TOB3calib=conf_.getParameter<double>("TOB3calib");
  TOB4calib=conf_.getParameter<double>("TOB4calib");
  TOB5calib=conf_.getParameter<double>("TOB5calib");
  TOB6calib=conf_.getParameter<double>("TOB6calib");
  }
  
  
  auto fitfunc= std::make_unique<TF1>("fitfunc","([4]/[3])*[1]*(TMath::Abs(x-[0]))+[2]",-1,1);
  auto fitfunc2IT= std::make_unique<TF1>("fitfunc2IT","([4]/[3])*[1]*(TMath::Abs(x-[0]))+[2]",-1,1);
 
  std::ofstream NoEntries;
  NoEntries.open(NoEntriesHisto_.c_str());
  std::ofstream Rep;
  Rep.open(LAreport_.c_str());
  
  gStyle->SetOptStat(1110);
  
  for(histo=histolist.begin();histo!=histolist.end();++histo){
  
  FitFunction = nullptr;
  FitFunction2IT = nullptr;
  bool Good2ITFit = false;
  bool ModuleHisto = true;
  
  histoEntries = -99;
  gphi=-99;
  geta=-99;
  gz = -99;
  gR=-1;
  globalX = -99;
  globalY = -99;
  globalZ = -99;
  goodFit = 0;
  goodFit1IT = 0;
  badFit = 0;
  muH = -1;
  TIB = 0;
  TOB = 0;
  MonoStereo = -1;
  
    uint32_t id=hidmanager.getComponentId((*histo)->getName());
    DetId detid(id);
    StripSubdetector subid(id);
    const GeomDetUnit * stripdet;
    MonoStereo = subid.stereo();
    
    if(!(stripdet=tracker->idToDetUnit(subid))){
    no_mod_histo++;
    ModuleHisto=false;
    edm::LogInfo("SiStripCalibLorentzAngle")<<"### NO MODULE HISTOGRAM";}
    
    if(stripdet!=nullptr && ModuleHisto==true){
    
      if(subid.subdetId() == int (StripSubdetector::TIB)){
      
      Layer = tTopo->tibLayer(detid);
      TIB = 1;}     
      if(subid.subdetId() == int (StripSubdetector::TOB)){
      
      Layer = tTopo->tobLayer(detid);
      TOB = 1;}
      
    //get module coordinates
    const GlobalPoint gposition = (stripdet->surface()).toGlobal(p);
    histoEntries = (*histo)->getEntries();
    globalX = gposition.x();
    globalY = gposition.y();
    globalZ = gposition.z();
    gphi = gposition.phi();
    geta = gposition.eta();
    gR = sqrt(pow(gposition.x(),2)+pow(gposition.y(),2));
    gz = gposition.z();
    
    //get magnetic field
    const StripGeomDetUnit* det = dynamic_cast<const StripGeomDetUnit*>(estracker->idToDetUnit(detid));
    if (det==nullptr){
    edm::LogError("SiStripCalibLorentzAngle") << "[SiStripCalibLorentzAngle::getNewObject] the detID " << id << " doesn't seem to belong to Tracker" <<std::endl;   
    continue;
    }
    LocalVector lbfield=(det->surface()).toLocal(magfield_->inTesla(det->surface().position()));
    theBfield = lbfield.mag();
    theBfield = (theBfield > 0) ? theBfield : 0.00001; 
    TH1Ds["MagneticField"]->Fill(theBfield);    
    }
    if(stripdet==nullptr)continue;
      
    if(((*histo)->getEntries()<=FitCuts_Entries)&&ModuleHisto==true){
    if(((*histo)->getEntries()==0)&&ModuleHisto==true){    
    NoEntries<<"NO ENTRIES MODULE, ID = "<<id<<std::endl;    
    edm::LogInfo("SiStripCalibLorentzAngle")<<"### HISTOGRAM WITH 0 ENTRIES => TYPE:"<<subid.subdetId();
    ZeroEntries++;
    }else{    
    edm::LogInfo("SiStripCalibLorentzAngle")<<"### HISTOGRAM WITH NR. ENTRIES <= ENTRIES_CUT => TYPE:"<<subid.subdetId();
    NotEnoughEntries++;}    
    }
    
      std::string name;
      if(TIB==1){
      name+="TIB";
      }else{
      name+="TOB";}
      std::stringstream LayerStream;
      LayerStream<<Layer;
      name+=LayerStream.str();    
      std::stringstream idnum;
      idnum<<id;
      name+="_Id_";
      name+=idnum.str();
      
    gStyle->SetOptFit(111);  
    
    //Extract TProfile from Monitor Element to ProfileMap
    Profiles[name] = new TProfile;   
    TProfile* theProfile=ExtractTObject<TProfile>().extract(*histo);   
    theProfile->Copy(*Profiles[name]);    
    Profiles[name]->SetName(name.c_str());
  
    if(((*histo)->getEntries()>FitCuts_Entries) && ModuleHisto==true){   
      histocounter++;            
      if(TIB==1){
      edm::LogInfo("SiStripCalibLorentzAngle")<<"TIB layer = "<<Layer;}    
      if(TOB==1){
      edm::LogInfo("SiStripCalibLorentzAngle")<<"TOB layer = "<<Layer;}     
      edm::LogInfo("SiStripCalibLorentzAngle")<<"id: "<<id;    
            
      float thickness=stripdet->specificSurface().bounds().thickness();
      const StripTopology& topol=(const StripTopology&)stripdet->topology();
      float pitch = topol.localPitch(p);
              
      fitfunc->SetParameter(0, p0_guess);
      fitfunc->SetParameter(1, p1_guess);
      fitfunc->SetParameter(2, p2_guess);
      fitfunc->FixParameter(3, pitch);
      fitfunc->FixParameter(4, thickness);
      
      Profiles[name]->Fit(fitfunc.get(),"E","",ModuleRangeMin, ModuleRangeMax);
            
      FitFunction = fitfunc.get();
      chi2norm = FitFunction->GetChisquare()/FitFunction->GetNDF();
      
      if(FitFunction->GetParameter(0)>FitCuts_p0 || FitFunction->GetParameter(1)<FitCuts_p1 || FitFunction->GetParameter(2)<FitCuts_p2 || chi2norm>FitCuts_chi2 || FitFunction->GetParError(0)<FitCuts_ParErr_p0){
      
      FirstIT_badfit++;   
            
      fitfunc2IT->SetParameter(0, p0_guess);
      fitfunc2IT->SetParameter(1, p1_guess);
      fitfunc2IT->SetParameter(2, p2_guess);
      fitfunc2IT->FixParameter(3, pitch);
      fitfunc2IT->FixParameter(4, thickness);
      
      //2nd Iteration
      Profiles[name]->Fit(fitfunc2IT.get(),"E","",ModuleRangeMin2IT, ModuleRangeMax2IT);
      
      FitFunction = fitfunc2IT.get();
      chi2norm = FitFunction->GetChisquare()/FitFunction->GetNDF();
                
      //2nd Iteration failed
      
      if(FitFunction->GetParameter(0)>FitCuts_p0 || FitFunction->GetParameter(1)<FitCuts_p1 || FitFunction->GetParameter(2)<FitCuts_p2 || chi2norm>FitCuts_chi2 || FitFunction->GetParError(0)<FitCuts_ParErr_p0){
      
      if(subid.subdetId() == int (StripSubdetector::TIB)){
      Profiles[name]->SetDirectory(TIB_2IT_BadFit);
      }else{
      Profiles[name]->SetDirectory(TOB_2IT_BadFit);} 
            
      SecondIT_badfit++;
      badFit=1;     
          
      }
      
      //2nd Iteration ok
     
      if(FitFunction->GetParameter(0)<FitCuts_p0 && FitFunction->GetParameter(1)>FitCuts_p1 && FitFunction->GetParameter(2)>FitCuts_p2 && chi2norm<FitCuts_chi2 && FitFunction->GetParError(0)>FitCuts_ParErr_p0){
      
      if(subid.subdetId() == int (StripSubdetector::TIB)){
      Profiles[name]->SetDirectory(TIB_2IT_GoodFit);
      }else{
      Profiles[name]->SetDirectory(TOB_2IT_GoodFit);} 
      
      SecondIT_goodfit++;      
      Good2ITFit = true;
      
      }
            
      }  
                       
      if(FitFunction->GetParameter(0)<FitCuts_p0 && FitFunction->GetParameter(1)>FitCuts_p1 && FitFunction->GetParameter(2)>FitCuts_p2 && chi2norm<FitCuts_chi2 && FitFunction->GetParError(0)>FitCuts_ParErr_p0){
      
    if(Good2ITFit==false){
    
    FirstIT_goodfit++;
    goodFit1IT = 1;
    
    if(subid.subdetId() == int (StripSubdetector::TIB)){
        Profiles[name]->SetDirectory(TIB_1IT_GoodFit);
        }else{
        Profiles[name]->SetDirectory(TOB_1IT_GoodFit);} 
    
    }
    
    GoodFit++;
    goodFit=1;
    
    LorentzAngle_Plots->cd();
            
    edm::LogInfo("SiStripCalibLorentzAngle")<<FitFunction->GetParameter(0);
    
    muH = -(FitFunction->GetParameter(0))/theBfield;
    
    if(TIB==1){
    if(Layer==1) muH = muH/TIB1calib;
    if(Layer==2) muH = muH/TIB2calib;
    if(Layer==3) muH = muH/TIB3calib;
    if(Layer==4) muH = muH/TIB4calib;
    }
    if(TOB==1){
    if(Layer==1) muH = muH/TOB1calib;
    if(Layer==2) muH = muH/TOB2calib;
    if(Layer==3) muH = muH/TOB3calib;
    if(Layer==4) muH = muH/TOB4calib;
    if(Layer==5) muH = muH/TOB5calib;
    if(Layer==6) muH = muH/TOB6calib;
    }
    
    detid_la[id]= muH;
    
    if(TIB==1){
    
    TH1Ds["LA_TIB"]->Fill(muH);
    TH1Ds["LA_err_TIB"]->Fill(FitFunction->GetParError(0)/theBfield);
    TH1Ds["LA_chi2norm_TIB"]->Fill(chi2norm);
    TH2Ds["LA_phi_TIB"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB"]->Fill(geta,muH);
    TH2Ds["LA_TIB_graph"]->Fill(Layer,muH);
    
    if(Layer==1){
    TH1Ds["LA_TIB_1"]->Fill(muH);
    TH2Ds["LA_phi_TIB1"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB1"]->Fill(geta,muH);
    if(MonoStereo==0){
    TH1Ds["LA_TIB_1_mono"]->Fill(muH);
    TH2Ds["LA_phi_TIB1_mono"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB1_mono"]->Fill(geta,muH);}
    if(MonoStereo==1){
    TH1Ds["LA_TIB_1_stereo"]->Fill(muH);
    TH2Ds["LA_phi_TIB1_stereo"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB1_stereo"]->Fill(geta,muH);}
    }
    
    if(Layer==2){
    TH1Ds["LA_TIB_2"]->Fill(muH);
    TH2Ds["LA_phi_TIB2"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB2"]->Fill(geta,muH);
    if(MonoStereo==0){
    TH1Ds["LA_TIB_2_mono"]->Fill(muH);
    TH2Ds["LA_phi_TIB2_mono"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB2_mono"]->Fill(geta,muH);}
    if(MonoStereo==1){
    TH1Ds["LA_TIB_2_stereo"]->Fill(muH);
    TH2Ds["LA_phi_TIB2_stereo"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB2_stereo"]->Fill(geta,muH);}
    }
    
    if(Layer==3){
    TH1Ds["LA_TIB_3"]->Fill(muH);
    TH2Ds["LA_phi_TIB3"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB3"]->Fill(geta,muH);
    }
    
    if(Layer==4){
    TH1Ds["LA_TIB_4"]->Fill(muH);
    TH2Ds["LA_phi_TIB4"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TIB4"]->Fill(geta,muH);
    }
    }   
    
    if(TOB==1){
    
        TH1Ds["LA_TOB"]->Fill(muH);
    TH1Ds["LA_err_TOB"]->Fill(FitFunction->GetParError(0)/theBfield);
    TH1Ds["LA_chi2norm_TOB"]->Fill(chi2norm);
    TH2Ds["LA_phi_TOB"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB"]->Fill(geta,muH);
    TH2Ds["LA_TOB_graph"]->Fill(Layer,muH);
    
    if(Layer==1){
    TH1Ds["LA_TOB_1"]->Fill(muH);
    TH2Ds["LA_phi_TOB1"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB1"]->Fill(geta,muH);
    if(MonoStereo==0){
    TH1Ds["LA_TOB_1_mono"]->Fill(muH);
    TH2Ds["LA_phi_TOB1_mono"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB1_mono"]->Fill(geta,muH);}
    if(MonoStereo==1){
    TH1Ds["LA_TOB_1_stereo"]->Fill(muH);
    TH2Ds["LA_phi_TOB1_stereo"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB1_stereo"]->Fill(geta,muH);}
    }
    
    if(Layer==2){
    TH1Ds["LA_TOB_2"]->Fill(muH);
    TH2Ds["LA_phi_TOB2"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB2"]->Fill(geta,muH);
    if(MonoStereo==0){
    TH1Ds["LA_TOB_2_mono"]->Fill(muH);
    TH2Ds["LA_phi_TOB2_mono"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB2_mono"]->Fill(geta,muH);}
    if(MonoStereo==1){
    TH1Ds["LA_TOB_2_stereo"]->Fill(muH);
    TH2Ds["LA_phi_TOB2_stereo"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB2_stereo"]->Fill(geta,muH);}
    }
    
    if(Layer==3){
    TH1Ds["LA_TOB_3"]->Fill(muH);
    TH2Ds["LA_phi_TOB3"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB3"]->Fill(geta,muH);
    }
    
    if(Layer==4){
    TH1Ds["LA_TOB_4"]->Fill(muH);
    TH2Ds["LA_phi_TOB4"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB4"]->Fill(geta,muH);
    }
    
    if(Layer==5){
    TH1Ds["LA_TOB_5"]->Fill(muH);
    TH2Ds["LA_phi_TOB5"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB5"]->Fill(geta,muH);
    }
    
    if(Layer==6){
    TH1Ds["LA_TOB_6"]->Fill(muH);
    TH2Ds["LA_phi_TOB6"]->Fill(gphi,muH);
    TH2Ds["LA_eta_TOB6"]->Fill(geta,muH);
    }
    }
    
       }
    }
    
    ModuleTree->Fill();
     
  }
  
  double GaussFitRange=conf_.getParameter<double>("GaussFitRange");
  auto gaus = std::make_unique<TF1>("gaus","gaus");
  
  TH1Ds["LA_TIB_1"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TIB1 = gaus->GetParameter(1);
  float err_mean_TIB1 = gaus->GetParError(1);
  float rms_TIB1 = gaus->GetParameter(2);
  TH1Ds["LA_TIB_2"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TIB2 = gaus->GetParameter(1);
  float err_mean_TIB2 = gaus->GetParError(1);
  float rms_TIB2 = gaus->GetParameter(2);
  TH1Ds["LA_TIB_3"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TIB3 = gaus->GetParameter(1);
  float err_mean_TIB3 = gaus->GetParError(1);
  float rms_TIB3 = gaus->GetParameter(2);
  TH1Ds["LA_TIB_4"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TIB4 = gaus->GetParameter(1);
  float err_mean_TIB4 = gaus->GetParError(1);
  float rms_TIB4 = gaus->GetParameter(2);

  TH1Ds["LA_TOB_1"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB1 = gaus->GetParameter(1);
  float err_mean_TOB1 = gaus->GetParError(1);
  float rms_TOB1 = gaus->GetParameter(2);
  TH1Ds["LA_TOB_2"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB2 = gaus->GetParameter(1);
  float err_mean_TOB2 = gaus->GetParError(1);
  float rms_TOB2 = gaus->GetParameter(2);
  TH1Ds["LA_TOB_3"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB3 = gaus->GetParameter(1);
  float err_mean_TOB3 = gaus->GetParError(1);
  float rms_TOB3 = gaus->GetParameter(2);
  TH1Ds["LA_TOB_4"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB4 = gaus->GetParameter(1);
  float err_mean_TOB4 = gaus->GetParError(1);
  float rms_TOB4 = gaus->GetParameter(2);
  TH1Ds["LA_TOB_5"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB5 = gaus->GetParameter(1);
  float err_mean_TOB5 = gaus->GetParError(1);
  float rms_TOB5 = gaus->GetParameter(2);
  TH1Ds["LA_TOB_6"]->Fit(gaus.get(),"","",-GaussFitRange,GaussFitRange);  
  mean_TOB6 = gaus->GetParameter(1);
  float err_mean_TOB6 = gaus->GetParError(1);
  float rms_TOB6 = gaus->GetParameter(2);

int nlayersTIB = 4;
float TIBx[4]={1,2,3,4};
float TIBex[4]={0,0,0,0};
float TIBy[4]={mean_TIB1, mean_TIB2, mean_TIB3, mean_TIB4};
float TIBey[4]={err_mean_TIB1, err_mean_TIB2, err_mean_TIB3, err_mean_TIB4};

int nlayersTOB = 6;
float TOBx[6]={1,2,3,4,5,6};
float TOBex[6]={0,0,0,0,0,0};
float TOBy[6]={mean_TOB1, mean_TOB2, mean_TOB3, mean_TOB4, mean_TOB5, mean_TOB6};
float TOBey[6]={err_mean_TOB1, err_mean_TOB2, err_mean_TOB3, err_mean_TOB4, err_mean_TOB5, err_mean_TOB6};

TIB_graph = new TGraphErrors(nlayersTIB,TIBx,TIBy,TIBex,TIBey);
TOB_graph = new TGraphErrors(nlayersTOB,TOBx,TOBy,TOBex,TOBey);

//TF1 *fit_TIB= new TF1("fit_TIB","[0]",0,4);
//TF1 *fit_TOB= new TF1("fit_TOB","[0]",0,6);

gStyle->SetOptFit(111);
gStyle->SetOptStat(111);

TIB_graph->SetTitle("TIB Layers #mu_{H}");
TIB_graph->GetXaxis()->SetTitle("Layers");
TIB_graph->GetXaxis()->SetNdivisions(4);
TIB_graph->GetYaxis()->SetTitle("#mu_{H}");
TIB_graph->SetMarkerStyle(20);
TIB_graph->GetYaxis()->SetTitleOffset(1.3);
TIB_graph->Fit("fit_TIB","E","",1,4);
meanMobility_TIB = TIB_graph->GetFunction("fit_TIB")->GetParameter(0);

TOB_graph->SetTitle("TOB Layers #mu_{H}");
TOB_graph->GetXaxis()->SetTitle("Layers");
TOB_graph->GetXaxis()->SetNdivisions(6);
TOB_graph->GetYaxis()->SetTitle("#mu_{H}");
TOB_graph->SetMarkerStyle(20);
TOB_graph->GetYaxis()->SetTitleOffset(1.3);
TOB_graph->Fit("fit_TOB","E","",1,6);
meanMobility_TOB = TOB_graph->GetFunction("fit_TOB")->GetParameter(0);

  TIB_graph->Write("TIB_graph");
  TOB_graph->Write("TOB_graph");

  Rep<<"- NR.OF TIB AND TOB MODULES = 7932"<<std::endl<<std::endl<<std::endl;
  Rep<<"- NO MODULE HISTOS FOUND = "<<no_mod_histo<<std::endl<<std::endl;
  Rep<<"- NR.OF HISTOS WITH ENTRIES > "<<FitCuts_Entries<<" = "<<histocounter<<std::endl<<std::endl;
  Rep<<"- NR.OF HISTOS WITH ENTRIES <= "<<FitCuts_Entries<<" (!=0) = "<<NotEnoughEntries<<std::endl<<std::endl;
  Rep<<"- NR.OF HISTOS WITH 0 ENTRIES = "<<ZeroEntries<<std::endl<<std::endl<<std::endl;
  Rep<<"- NR.OF GOOD FIT (FIRST IT + SECOND IT GOOD FIT)= "<<GoodFit<<std::endl<<std::endl;
  Rep<<"- NR.OF FIRST IT GOOD FIT = "<<FirstIT_goodfit<<std::endl<<std::endl;
  Rep<<"- NR.OF SECOND IT GOOD FIT = "<<SecondIT_goodfit<<std::endl<<std::endl;
  Rep<<"- NR.OF FIRST IT BAD FIT = "<<FirstIT_badfit<<std::endl<<std::endl;
  Rep<<"- NR.OF SECOND IT BAD FIT = "<<SecondIT_badfit<<std::endl<<std::endl<<std::endl;
  
  Rep<<"--------------- Mean MuH values per Layer -------------------"<<std::endl<<std::endl<<std::endl;
  Rep<<"TIB1 = "<<mean_TIB1<<" +- "<<err_mean_TIB1<<" RMS = "<<rms_TIB1<<std::endl;
  Rep<<"TIB2 = "<<mean_TIB2<<" +- "<<err_mean_TIB2<<" RMS = "<<rms_TIB2<<std::endl;
  Rep<<"TIB3 = "<<mean_TIB3<<" +- "<<err_mean_TIB3<<" RMS = "<<rms_TIB3<<std::endl;
  Rep<<"TIB4 = "<<mean_TIB4<<" +- "<<err_mean_TIB4<<" RMS = "<<rms_TIB4<<std::endl;
  Rep<<"TOB1 = "<<mean_TOB1<<" +- "<<err_mean_TOB1<<" RMS = "<<rms_TOB1<<std::endl;
  Rep<<"TOB2 = "<<mean_TOB2<<" +- "<<err_mean_TOB2<<" RMS = "<<rms_TOB2<<std::endl;
  Rep<<"TOB3 = "<<mean_TOB3<<" +- "<<err_mean_TOB3<<" RMS = "<<rms_TOB3<<std::endl;
  Rep<<"TOB4 = "<<mean_TOB4<<" +- "<<err_mean_TOB4<<" RMS = "<<rms_TOB4<<std::endl;
  Rep<<"TOB5 = "<<mean_TOB5<<" +- "<<err_mean_TOB5<<" RMS = "<<rms_TOB5<<std::endl;
  Rep<<"TOB6 = "<<mean_TOB6<<" +- "<<err_mean_TOB6<<" RMS = "<<rms_TOB6<<std::endl<<std::endl;
  Rep<<"Mean Hall Mobility TIB = "<<meanMobility_TIB<<" +- "<<TIB_graph->GetFunction("fit_TIB")->GetParError(0)<<std::endl;
  Rep<<"Mean Hall Mobility TOB = "<<meanMobility_TOB<<" +- "<<TOB_graph->GetFunction("fit_TOB")->GetParError(0)<<std::endl<<std::endl<<std::endl;
        
  Rep.close();
  NoEntries.close(); 
  
hFile->Write();
hFile->Close();
    
}

std::unique_ptr< SiStripLorentzAngle > SiStripCalibLorentzAngle::getNewObject ( )

overridevirtual

Implements ConditionDBWriter< SiStripLorentzAngle >.

Definition at line 769 of file SiStripCalibLorentzAngle.cc.

References detid_la, TrackerGeometry::detIds(), estracker, hallMobility, createfilelist::int, LayerDB, SiStripSimParameters_cfi::LorentzAngle, mean_TIB1, mean_TIB2, mean_TIB3, mean_TIB4, mean_TOB1, mean_TOB2, mean_TOB3, mean_TOB4, mean_TOB5, mean_TOB6, meanMobility_TIB, meanMobility_TOB, StripSubdetector::TEC, TrackerTopology::tecRing(), StripSubdetector::TIB, TrackerTopology::tibLayer(), StripSubdetector::TID, StripSubdetector::TOB, TrackerTopology::tobLayer(), and tTopo.

                                                                         {

  auto LorentzAngle = std::make_unique<SiStripLorentzAngle>();
  
  if(!LayerDB){
  for(std::map<uint32_t, float>::iterator it = detid_la.begin(); it != detid_la.end(); it++){
    
    float langle=it->second;
    if ( ! LorentzAngle->putLorentzAngle(it->first,langle) )
      edm::LogError("SiStripCalibLorentzAngle")<<"[SiStripCalibLorentzAngle::analyze] detid already exists"<<std::endl;
  }
  }
  
  else{
  
    const TrackerGeometry::DetIdContainer& Id = estracker->detIds();
    TrackerGeometry::DetIdContainer::const_iterator Iditer; 
       
    for(Iditer=Id.begin();Iditer!=Id.end();Iditer++){
  
    StripSubdetector subid(Iditer->rawId());
    
    hallMobility = 0.;
    
    if(subid.subdetId() == int (StripSubdetector::TIB)){
    
    uint32_t tibLayer = tTopo->tibLayer(*Iditer);
    if(tibLayer==1){
    hallMobility=mean_TIB1;}
    if(tibLayer==2){
    hallMobility=mean_TIB2;}
    if(tibLayer==3){
    hallMobility=mean_TIB3;}
    if(tibLayer==4){
    hallMobility=mean_TIB4;}
    if (!LorentzAngle->putLorentzAngle(Iditer->rawId(),hallMobility)) edm::LogError("SiStripLorentzAngleGenerator")<<" detid already exists"<<std::endl;
    }
    
    if(subid.subdetId() == int (StripSubdetector::TOB)){
    
    uint32_t tobLayer = tTopo->tobLayer(*Iditer);
    if(tobLayer==1){
    hallMobility=mean_TOB1;}
    if(tobLayer==2){
    hallMobility=mean_TOB2;}
    if(tobLayer==3){
    hallMobility=mean_TOB3;}
    if(tobLayer==4){
    hallMobility=mean_TOB4;}
    if(tobLayer==5){
    hallMobility=mean_TOB5;}
    if(tobLayer==6){
    hallMobility=mean_TOB6;}
    if (!LorentzAngle->putLorentzAngle(Iditer->rawId(),hallMobility)) edm::LogError("SiStripLorentzAngleGenerator")<<" detid already exists"<<std::endl;
    } 
     
    if( subid.subdetId() == int(StripSubdetector::TID) ) {
    hallMobility=meanMobility_TIB;
    if (!LorentzAngle->putLorentzAngle(Iditer->rawId(),hallMobility)) edm::LogError("SiStripLorentzAngleGenerator")<<" detid already exists"<<std::endl;
    } 
    
    if( subid.subdetId() == int(StripSubdetector::TEC) ) {
    
    if(tTopo->tecRing(subid)<5 ) {
    hallMobility=meanMobility_TIB;
    }else{
    hallMobility=meanMobility_TOB;
    }
    if (!LorentzAngle->putLorentzAngle(Iditer->rawId(),hallMobility)) edm::LogError("SiStripLorentzAngleGenerator")<<" detid already exists"<<std::endl;
    }
                 
  }
  }
  
  return LorentzAngle;
  
}

Member Data Documentation

float SiStripCalibLorentzAngle::AsymmParam

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

int SiStripCalibLorentzAngle::badFit

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

bool SiStripCalibLorentzAngle::CalibByMC

private

Definition at line 76 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

edm::ParameterSet SiStripCalibLorentzAngle::conf_

private

Definition at line 87 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

std::map< uint32_t, float> SiStripCalibLorentzAngle::detid_la

private

Definition at line 86 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

edm::ESHandle<TrackerGeometry> SiStripCalibLorentzAngle::estracker

private

Definition at line 52 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

TDirectory* SiStripCalibLorentzAngle::FirstIT_GoodFit_Histos

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TF1* SiStripCalibLorentzAngle::fitfunc

private

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TF1 * SiStripCalibLorentzAngle::fitfunc2IT

private

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TF1 * SiStripCalibLorentzAngle::FitFunction

private

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TF1 * SiStripCalibLorentzAngle::FitFunction2IT

private

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::geta

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::globalX

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::globalY

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::globalZ

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::goodFit

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::goodFit1IT

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::gphi

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

const GlobalPoint SiStripCalibLorentzAngle::gposition

private

Definition at line 70 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::gR

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::gz

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::hallMobility

private

Definition at line 74 of file SiStripCalibLorentzAngle.h.

Referenced by getNewObject().

TFile* SiStripCalibLorentzAngle::hFile

private

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and ~SiStripCalibLorentzAngle().

float SiStripCalibLorentzAngle::histoEntries

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

std::vector<MonitorElement*> SiStripCalibLorentzAngle::histolist

private

Definition at line 64 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::Layer

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

bool SiStripCalibLorentzAngle::LayerDB

private

Definition at line 76 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

TDirectory* SiStripCalibLorentzAngle::LorentzAngle_Plots

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

edm::ESHandle<MagneticField> SiStripCalibLorentzAngle::magfield_

private

Definition at line 53 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::mean_TIB1

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TIB2

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TIB3

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TIB4

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB1

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB2

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB3

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB4

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB5

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::mean_TOB6

private

Definition at line 72 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::meanMobility_TIB

private

Definition at line 74 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

float SiStripCalibLorentzAngle::meanMobility_TOB

private

Definition at line 74 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

TTree* SiStripCalibLorentzAngle::ModuleTree

private

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::MonoStereo

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::muH

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH_vs_Eta

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH_vs_Phi

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

ProfileMap SiStripCalibLorentzAngle::Profiles

private

Definition at line 59 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::Rootple

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::SecondIT_BadFit_Histos

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::SecondIT_GoodFit_Histos

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TH1Dmap SiStripCalibLorentzAngle::TH1Ds

private

Definition at line 61 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TH2Dmap SiStripCalibLorentzAngle::TH2Ds

private

Definition at line 63 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

float SiStripCalibLorentzAngle::theBfield

private

Definition at line 68 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::TIB

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_1IT_GoodFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_2IT_BadFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_2IT_GoodFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_Eta

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TGraphErrors* SiStripCalibLorentzAngle::TIB_graph

private

Definition at line 78 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_MuH

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_Phi

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

int SiStripCalibLorentzAngle::TOB

private

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_1IT_GoodFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_2IT_BadFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_2IT_GoodFit

private

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_Eta

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TGraphErrors * SiStripCalibLorentzAngle::TOB_graph

private

Definition at line 78 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_MuH

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_Phi

private

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

const TrackerGeometry* SiStripCalibLorentzAngle::tracker

private

Definition at line 55 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

const TrackerTopology* SiStripCalibLorentzAngle::tTopo

private

Definition at line 56 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().