MuonAlignmentAnalyzer Class Reference

#include <MuonAlignmentAnalyzer.h>

Inheritance diagram for MuonAlignmentAnalyzer:

Public Member Functions
void	analyze (const edm::Event &event, const edm::EventSetup &eventSetup) override
void	beginJob () override
void	endJob () override
	MuonAlignmentAnalyzer (const edm::ParameterSet &pset)
	Constructor. More...
	~MuonAlignmentAnalyzer () override
	Destructor. More...
Public Member Functions inherited from edm::one::EDAnalyzer< edm::one::SharedResources >
	EDAnalyzer ()=default
SerialTaskQueue *	globalLuminosityBlocksQueue () final
SerialTaskQueue *	globalRunsQueue () final
bool	wantsGlobalLuminosityBlocks () const final
bool	wantsGlobalRuns () const final
bool	wantsInputProcessBlocks () const final
bool	wantsProcessBlocks () const final
Public Member Functions inherited from edm::one::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzerBase ()
ModuleDescription const &	moduleDescription () const
bool	wantsStreamLuminosityBlocks () const
bool	wantsStreamRuns () const
	~EDAnalyzerBase () 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 &&)=default
	EDConsumerBase (EDConsumerBase const &)=delete
ESProxyIndex const *	esGetTokenIndices (edm::Transition iTrans) const
std::vector< ESProxyIndex > const &	esGetTokenIndicesVector (edm::Transition iTrans) const
std::vector< ESRecordIndex > const &	esGetTokenRecordIndicesVector (edm::Transition iTrans) const
ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
EDConsumerBase &	operator= (EDConsumerBase &&)=default
EDConsumerBase const &	operator= (EDConsumerBase const &)=delete
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 Member Functions
RecHitVector	doMatching (const reco::Track &, edm::Handle< DTRecSegment4DCollection > &, edm::Handle< CSCSegmentCollection > &, intDVector *, intDVector *, edm::ESHandle< GlobalTrackingGeometry > &)

Private Attributes
std::vector< long >	detectorCollection
bool	doGBplots
bool	doResplots
bool	doSAplots
edm::Service< TFileService >	fs
TH1F *	hGBChi2
TH1F *	hGBChi2_Barrel
TH1F *	hGBChi2_Endcap
TH1F *	hGBInvM
TH1F *	hGBInvM_Barrel
TH1F *	hGBInvM_Endcap
TH1F *	hGBInvM_Overlap
TH1F *	hGBinvPTres
TH2F *	hGBinvPTvsEta
TH2F *	hGBinvPTvsNhits
TH2F *	hGBinvPTvsPhi
TH1F *	hGBNhits
TH1F *	hGBNhits_Barrel
TH1F *	hGBNhits_Endcap
TH1F *	hGBNmuons
TH1F *	hGBNmuons_Barrel
TH1F *	hGBNmuons_Endcap
TH2F *	hGBPhivsEta
TH1F *	hGBPTDiff
TH2F *	hGBPTDiffvsEta
TH2F *	hGBPTDiffvsPhi
TH1F *	hGBPTRec
TH1F *	hGBPTRec_Barrel
TH1F *	hGBPTRec_Endcap
TH1F *	hGBPTres
TH1F *	hGBPTres_Barrel
TH1F *	hGBPTres_Endcap
TH2F *	hGBPTvsEta
TH2F *	hGBPTvsPhi
TH2F *	hprofGlobalAngleCSC
TH2F *	hprofGlobalAngleDT
TH2F *	hprofGlobalAngleRmsCSC
TH2F *	hprofGlobalAngleRmsDT
TH1F *	hprofGlobalPhiCSC
TH1F *	hprofGlobalPhiDT
TH2F *	hprofGlobalPositionCSC
TH2F *	hprofGlobalPositionDT
TH2F *	hprofGlobalPositionRmsCSC
TH2F *	hprofGlobalPositionRmsDT
TH1F *	hprofGlobalRCSC
TH1F *	hprofGlobalRPhiCSC
TH1F *	hprofGlobalRPhiDT
TH1F *	hprofGlobalThetaCSC
TH1F *	hprofGlobalThetaDT
TH1F *	hprofGlobalZDT
TH2F *	hprofLocalAngleCSC
TH2F *	hprofLocalAngleDT
TH2F *	hprofLocalAngleRmsCSC
TH2F *	hprofLocalAngleRmsDT
TH1F *	hprofLocalPhiCSC
TH1F *	hprofLocalPhiDT
TH2F *	hprofLocalPositionCSC
TH2F *	hprofLocalPositionDT
TH2F *	hprofLocalPositionRmsCSC
TH2F *	hprofLocalPositionRmsDT
TH1F *	hprofLocalThetaCSC
TH1F *	hprofLocalThetaDT
TH1F *	hprofLocalXCSC
TH1F *	hprofLocalXDT
TH1F *	hprofLocalYCSC
TH1F *	hprofLocalYDT
TH1F *	hResidualGlobalPhiCSC
std::vector< TH1F * >	hResidualGlobalPhiCSC_ME
TH1F *	hResidualGlobalPhiDT
std::vector< TH1F * >	hResidualGlobalPhiDT_MB
std::vector< TH1F * >	hResidualGlobalPhiDT_W
TH1F *	hResidualGlobalRCSC
std::vector< TH1F * >	hResidualGlobalRCSC_ME
TH1F *	hResidualGlobalRPhiCSC
std::vector< TH1F * >	hResidualGlobalRPhiCSC_ME
TH1F *	hResidualGlobalRPhiDT
std::vector< TH1F * >	hResidualGlobalRPhiDT_MB
std::vector< TH1F * >	hResidualGlobalRPhiDT_W
TH1F *	hResidualGlobalThetaCSC
std::vector< TH1F * >	hResidualGlobalThetaCSC_ME
TH1F *	hResidualGlobalThetaDT
std::vector< TH1F * >	hResidualGlobalThetaDT_MB
std::vector< TH1F * >	hResidualGlobalThetaDT_W
TH1F *	hResidualGlobalZDT
std::vector< TH1F * >	hResidualGlobalZDT_MB
std::vector< TH1F * >	hResidualGlobalZDT_W
TH1F *	hResidualLocalPhiCSC
std::vector< TH1F * >	hResidualLocalPhiCSC_ME
TH1F *	hResidualLocalPhiDT
std::vector< TH1F * >	hResidualLocalPhiDT_MB
std::vector< TH1F * >	hResidualLocalPhiDT_W
TH1F *	hResidualLocalThetaCSC
std::vector< TH1F * >	hResidualLocalThetaCSC_ME
TH1F *	hResidualLocalThetaDT
std::vector< TH1F * >	hResidualLocalThetaDT_MB
std::vector< TH1F * >	hResidualLocalThetaDT_W
TH1F *	hResidualLocalXCSC
std::vector< TH1F * >	hResidualLocalXCSC_ME
TH1F *	hResidualLocalXDT
std::vector< TH1F * >	hResidualLocalXDT_MB
std::vector< TH1F * >	hResidualLocalXDT_W
TH1F *	hResidualLocalYCSC
std::vector< TH1F * >	hResidualLocalYCSC_ME
TH1F *	hResidualLocalYDT
std::vector< TH1F * >	hResidualLocalYDT_MB
std::vector< TH1F * >	hResidualLocalYDT_W
TH1F *	hSAChi2
TH1F *	hSAChi2_Barrel
TH1F *	hSAChi2_Endcap
TH1F *	hSAInvM
TH1F *	hSAInvM_Barrel
TH1F *	hSAInvM_Endcap
TH1F *	hSAInvM_Overlap
TH1F *	hSAinvPTres
TH2F *	hSAinvPTvsEta
TH2F *	hSAinvPTvsNhits
TH2F *	hSAinvPTvsPhi
TH1F *	hSANhits
TH1F *	hSANhits_Barrel
TH1F *	hSANhits_Endcap
TH1F *	hSANmuons
TH1F *	hSANmuons_Barrel
TH1F *	hSANmuons_Endcap
TH2F *	hSAPhivsEta
TH1F *	hSAPTDiff
TH2F *	hSAPTDiffvsEta
TH2F *	hSAPTDiffvsPhi
TH1F *	hSAPTRec
TH1F *	hSAPTRec_Barrel
TH1F *	hSAPTRec_Endcap
TH1F *	hSAPTres
TH1F *	hSAPTres_Barrel
TH1F *	hSAPTres_Endcap
TH2F *	hSAPTvsEta
TH2F *	hSAPTvsPhi
TH1F *	hSimInvM
TH1F *	hSimInvM_Barrel
TH1F *	hSimInvM_Endcap
TH1F *	hSimInvM_Overlap
TH1F *	hSimNmuons
TH1F *	hSimNmuons_Barrel
TH1F *	hSimNmuons_Endcap
TH2F *	hSimPhivsEta
TH1F *	hSimPT
TH1F *	hSimPT_Barrel
TH1F *	hSimPT_Endcap
TH2F *	hSimPTvsEta
TH2F *	hSimPTvsPhi
double	invMassRangeMax
double	invMassRangeMin
const edm::ESGetToken< MagneticField, IdealMagneticFieldRecord >	magFieldToken_
unsigned int	min1DTrackRecHitSize
unsigned int	min4DTrackSegmentSize
unsigned int	nbins
int	numberOfGBRecTracks
int	numberOfHits
int	numberOfSARecTracks
int	numberOfSimTracks
double	ptRangeMax
double	ptRangeMin
double	resLocalXRangeStation1
double	resLocalXRangeStation2
double	resLocalXRangeStation3
double	resLocalXRangeStation4
double	resLocalYRangeStation1
double	resLocalYRangeStation2
double	resLocalYRangeStation3
double	resLocalYRangeStation4
double	resPhiRange
double	resThetaRange
std::string	theDataType
edm::InputTag	theGLBMuonTag
Propagator *	thePropagator
edm::InputTag	theRecHits4DTagCSC
edm::InputTag	theRecHits4DTagDT
edm::InputTag	theSTAMuonTag
const edm::ESGetToken< GlobalTrackingGeometry, GlobalTrackingGeometryRecord >	trackingGeometryToken_
std::vector< TH1F * >	unitsGlobalPhi
std::vector< TH1F * >	unitsGlobalRPhi
std::vector< TH1F * >	unitsGlobalRZ
std::vector< TH1F * >	unitsGlobalTheta
std::vector< TH1F * >	unitsLocalPhi
std::vector< TH1F * >	unitsLocalTheta
std::vector< TH1F * >	unitsLocalX
std::vector< TH1F * >	unitsLocalY

Additional Inherited Members
Public Types inherited from edm::one::EDAnalyzerBase
typedef EDAnalyzerBase	ModuleType
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Static Public Member Functions inherited from edm::one::EDAnalyzerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)
Protected Member Functions inherited from edm::EDConsumerBase
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B >	consumes (edm::InputTag tag) noexcept
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<Transition Tr = Transition::Event>
constexpr auto	esConsumes () noexcept
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)
template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag) noexcept
template<Transition Tr = Transition::Event>
ESGetTokenGeneric	esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
	Used with EventSetupRecord::doGet. More...
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

Detailed Description

MuonAlignment offline Monitor Analyzer Makes histograms of high level Muon objects/quantities for Alignment Scenarios/DB comparison

Date

2011/09/04 17:40:58

Revision

1.13

Author

J. Fernandez - Univ. Oviedo Javie.nosp@m.r.Fe.nosp@m.rnand.nosp@m.ez@c.nosp@m.ern.c.nosp@m.h

Definition at line 43 of file MuonAlignmentAnalyzer.h.

Constructor & Destructor Documentation

MuonAlignmentAnalyzer()

MuonAlignmentAnalyzer::MuonAlignmentAnalyzer

(

const edm::ParameterSet &

pset

)

Constructor.

Definition at line 46 of file MuonAlignmentAnalyzer.cc.

    : magFieldToken_(esConsumes()),
      trackingGeometryToken_(esConsumes()),
      hGBNmuons(nullptr),
      hSANmuons(nullptr),
      hSimNmuons(nullptr),
      hGBNmuons_Barrel(nullptr),
      hSANmuons_Barrel(nullptr),
      hSimNmuons_Barrel(nullptr),
      hGBNmuons_Endcap(nullptr),
      hSANmuons_Endcap(nullptr),
      hSimNmuons_Endcap(nullptr),
      hGBNhits(nullptr),
      hGBNhits_Barrel(nullptr),
      hGBNhits_Endcap(nullptr),
      hSANhits(nullptr),
      hSANhits_Barrel(nullptr),
      hSANhits_Endcap(nullptr),
      hGBChi2(nullptr),
      hSAChi2(nullptr),
      hGBChi2_Barrel(nullptr),
      hSAChi2_Barrel(nullptr),
      hGBChi2_Endcap(nullptr),
      hSAChi2_Endcap(nullptr),
      hGBInvM(nullptr),
      hSAInvM(nullptr),
      hSimInvM(nullptr),
      hGBInvM_Barrel(nullptr),
      hSAInvM_Barrel(nullptr),
      hSimInvM_Barrel(nullptr),
      hGBInvM_Endcap(nullptr),
      hSAInvM_Endcap(nullptr),
      hSimInvM_Endcap(nullptr),
      hGBInvM_Overlap(nullptr),
      hSAInvM_Overlap(nullptr),
      hSimInvM_Overlap(nullptr),
      hSAPTRec(nullptr),
      hGBPTRec(nullptr),
      hSimPT(nullptr),
      hSAPTRec_Barrel(nullptr),
      hGBPTRec_Barrel(nullptr),
      hSimPT_Barrel(nullptr),
      hSAPTRec_Endcap(nullptr),
      hGBPTRec_Endcap(nullptr),
      hSimPT_Endcap(nullptr),
      hGBPTvsEta(nullptr),
      hGBPTvsPhi(nullptr),
      hSAPTvsEta(nullptr),
      hSAPTvsPhi(nullptr),
      hSimPTvsEta(nullptr),
      hSimPTvsPhi(nullptr),
      hSimPhivsEta(nullptr),
      hSAPhivsEta(nullptr),
      hGBPhivsEta(nullptr),
      hSAPTres(nullptr),
      hSAinvPTres(nullptr),
      hGBPTres(nullptr),
      hGBinvPTres(nullptr),
      hSAPTres_Barrel(nullptr),
      hSAPTres_Endcap(nullptr),
      hGBPTres_Barrel(nullptr),
      hGBPTres_Endcap(nullptr),
      hSAPTDiff(nullptr),
      hGBPTDiff(nullptr),
      hSAPTDiffvsEta(nullptr),
      hSAPTDiffvsPhi(nullptr),
      hGBPTDiffvsEta(nullptr),
      hGBPTDiffvsPhi(nullptr),
      hGBinvPTvsEta(nullptr),
      hGBinvPTvsPhi(nullptr),
      hSAinvPTvsEta(nullptr),
      hSAinvPTvsPhi(nullptr),
      hSAinvPTvsNhits(nullptr),
      hGBinvPTvsNhits(nullptr),
      hResidualLocalXDT(nullptr),
      hResidualLocalPhiDT(nullptr),
      hResidualLocalThetaDT(nullptr),
      hResidualLocalYDT(nullptr),
      hResidualLocalXCSC(nullptr),
      hResidualLocalPhiCSC(nullptr),
      hResidualLocalThetaCSC(nullptr),
      hResidualLocalYCSC(nullptr),
 
      hResidualLocalXDT_W(5),
      hResidualLocalPhiDT_W(5),
      hResidualLocalThetaDT_W(5),
      hResidualLocalYDT_W(5),
      hResidualLocalXCSC_ME(18),
      hResidualLocalPhiCSC_ME(18),
      hResidualLocalThetaCSC_ME(18),
      hResidualLocalYCSC_ME(18),
      hResidualLocalXDT_MB(20),
      hResidualLocalPhiDT_MB(20),
      hResidualLocalThetaDT_MB(20),
      hResidualLocalYDT_MB(20),
 
      hResidualGlobalRPhiDT(nullptr),
      hResidualGlobalPhiDT(nullptr),
      hResidualGlobalThetaDT(nullptr),
      hResidualGlobalZDT(nullptr),
      hResidualGlobalRPhiCSC(nullptr),
      hResidualGlobalPhiCSC(nullptr),
      hResidualGlobalThetaCSC(nullptr),
      hResidualGlobalRCSC(nullptr),
 
      hResidualGlobalRPhiDT_W(5),
      hResidualGlobalPhiDT_W(5),
      hResidualGlobalThetaDT_W(5),
      hResidualGlobalZDT_W(5),
      hResidualGlobalRPhiCSC_ME(18),
      hResidualGlobalPhiCSC_ME(18),
      hResidualGlobalThetaCSC_ME(18),
      hResidualGlobalRCSC_ME(18),
      hResidualGlobalRPhiDT_MB(20),
      hResidualGlobalPhiDT_MB(20),
      hResidualGlobalThetaDT_MB(20),
      hResidualGlobalZDT_MB(20),
 
      hprofLocalPositionCSC(nullptr),
      hprofLocalAngleCSC(nullptr),
      hprofLocalPositionRmsCSC(nullptr),
      hprofLocalAngleRmsCSC(nullptr),
      hprofGlobalPositionCSC(nullptr),
      hprofGlobalAngleCSC(nullptr),
      hprofGlobalPositionRmsCSC(nullptr),
      hprofGlobalAngleRmsCSC(nullptr),
      hprofLocalPositionDT(nullptr),
      hprofLocalAngleDT(nullptr),
      hprofLocalPositionRmsDT(nullptr),
      hprofLocalAngleRmsDT(nullptr),
      hprofGlobalPositionDT(nullptr),
      hprofGlobalAngleDT(nullptr),
      hprofGlobalPositionRmsDT(nullptr),
      hprofGlobalAngleRmsDT(nullptr),
      hprofLocalXDT(nullptr),
      hprofLocalPhiDT(nullptr),
      hprofLocalThetaDT(nullptr),
      hprofLocalYDT(nullptr),
      hprofLocalXCSC(nullptr),
      hprofLocalPhiCSC(nullptr),
      hprofLocalThetaCSC(nullptr),
      hprofLocalYCSC(nullptr),
      hprofGlobalRPhiDT(nullptr),
      hprofGlobalPhiDT(nullptr),
      hprofGlobalThetaDT(nullptr),
      hprofGlobalZDT(nullptr),
      hprofGlobalRPhiCSC(nullptr),
      hprofGlobalPhiCSC(nullptr),
      hprofGlobalThetaCSC(nullptr),
      hprofGlobalRCSC(nullptr) {
  usesResource(TFileService::kSharedResource);
 
  theSTAMuonTag = pset.getParameter<edm::InputTag>("StandAloneTrackCollectionTag");
  theGLBMuonTag = pset.getParameter<edm::InputTag>("GlobalMuonTrackCollectionTag");
 
  theRecHits4DTagDT = pset.getParameter<edm::InputTag>("RecHits4DDTCollectionTag");
  theRecHits4DTagCSC = pset.getParameter<edm::InputTag>("RecHits4DCSCCollectionTag");
 
  theDataType = pset.getUntrackedParameter<std::string>("DataType");
  ptRangeMin = pset.getUntrackedParameter<double>("ptRangeMin");
  ptRangeMax = pset.getUntrackedParameter<double>("ptRangeMax");
  invMassRangeMin = pset.getUntrackedParameter<double>("invMassRangeMin");
  invMassRangeMax = pset.getUntrackedParameter<double>("invMassRangeMax");
 
  doSAplots = pset.getUntrackedParameter<bool>("doSAplots");
  doGBplots = pset.getUntrackedParameter<bool>("doGBplots");
  doResplots = pset.getUntrackedParameter<bool>("doResplots");
 
  resLocalXRangeStation1 = pset.getUntrackedParameter<double>("resLocalXRangeStation1");
  resLocalXRangeStation2 = pset.getUntrackedParameter<double>("resLocalXRangeStation2");
  resLocalXRangeStation3 = pset.getUntrackedParameter<double>("resLocalXRangeStation3");
  resLocalXRangeStation4 = pset.getUntrackedParameter<double>("resLocalXRangeStation4");
  resLocalYRangeStation1 = pset.getUntrackedParameter<double>("resLocalYRangeStation1");
  resLocalYRangeStation2 = pset.getUntrackedParameter<double>("resLocalYRangeStation2");
  resLocalYRangeStation3 = pset.getUntrackedParameter<double>("resLocalYRangeStation3");
  resLocalYRangeStation4 = pset.getUntrackedParameter<double>("resLocalYRangeStation4");
  resPhiRange = pset.getUntrackedParameter<double>("resPhiRange");
  resThetaRange = pset.getUntrackedParameter<double>("resThetaRange");
  nbins = pset.getUntrackedParameter<unsigned int>("nbins");
  min1DTrackRecHitSize = pset.getUntrackedParameter<unsigned int>("min1DTrackRecHitSize");
  min4DTrackSegmentSize = pset.getUntrackedParameter<unsigned int>("min4DTrackSegmentSize");
 
  if (theDataType != "RealData" && theDataType != "SimData")
    edm::LogError("MuonAlignmentAnalyzer") << "Error in Data Type!!" << std::endl;
 
  numberOfSimTracks = 0;
  numberOfSARecTracks = 0;
  numberOfGBRecTracks = 0;
  numberOfHits = 0;
}

References doGBplots, doResplots, doSAplots, invMassRangeMax, invMassRangeMin, TFileService::kSharedResource, min1DTrackRecHitSize, min4DTrackSegmentSize, nbins, numberOfGBRecTracks, numberOfHits, numberOfSARecTracks, numberOfSimTracks, muonDTDigis_cfi::pset, ptRangeMax, ptRangeMin, resLocalXRangeStation1, resLocalXRangeStation2, resLocalXRangeStation3, resLocalXRangeStation4, resLocalYRangeStation1, resLocalYRangeStation2, resLocalYRangeStation3, resLocalYRangeStation4, resPhiRange, resThetaRange, AlCaHLTBitMon_QueryRunRegistry::string, theDataType, theGLBMuonTag, theRecHits4DTagCSC, theRecHits4DTagDT, and theSTAMuonTag.

~MuonAlignmentAnalyzer()

MuonAlignmentAnalyzer::~MuonAlignmentAnalyzer ( )

override

Destructor.

Definition at line 238 of file MuonAlignmentAnalyzer.cc.

{}

Member Function Documentation

analyze()

void MuonAlignmentAnalyzer::analyze ( const edm::Event &  event, const edm::EventSetup &  eventSetup  )

overridevirtual

Implements edm::one::EDAnalyzerBase.

Definition at line 1720 of file MuonAlignmentAnalyzer.cc.

                                                                                          {
  GlobalVector p1, p2;
  std::vector<double> simPar[4];  //pt,eta,phi,charge
 
  // ######### if data= MC, do Simulation Plots#####
  if (theDataType == "SimData") {
    double simEta = 0;
    double simPt = 0;
    double simPhi = 0;
    int i = 0, ie = 0, ib = 0;
 
    // Get the SimTrack collection from the event
    edm::Handle<edm::SimTrackContainer> simTracks;
    event.getByLabel("g4SimHits", simTracks);
 
    edm::SimTrackContainer::const_iterator simTrack;
 
    for (simTrack = simTracks->begin(); simTrack != simTracks->end(); ++simTrack) {
      if (abs((*simTrack).type()) == 13) {
        i++;
        simPt = (*simTrack).momentum().Pt();
        simEta = (*simTrack).momentum().eta();
        simPhi = (*simTrack).momentum().phi();
        numberOfSimTracks++;
        hSimPT->Fill(simPt);
        if (fabs(simEta) < 1.04) {
          hSimPT_Barrel->Fill(simPt);
          ib++;
        } else {
          hSimPT_Endcap->Fill(simPt);
          ie++;
        }
        hSimPTvsEta->Fill(simEta, simPt);
        hSimPTvsPhi->Fill(simPhi, simPt);
        hSimPhivsEta->Fill(simEta, simPhi);
 
        simPar[0].push_back(simPt);
        simPar[1].push_back(simEta);
        simPar[2].push_back(simPhi);
        simPar[3].push_back((*simTrack).charge());
 
        //  Save the muon pair
        if (i == 1)
          p1 = GlobalVector((*simTrack).momentum().x(), (*simTrack).momentum().y(), (*simTrack).momentum().z());
        if (i == 2)
          p2 = GlobalVector((*simTrack).momentum().x(), (*simTrack).momentum().y(), (*simTrack).momentum().z());
      }
    }
    hSimNmuons->Fill(i);
    hSimNmuons_Barrel->Fill(ib);
    hSimNmuons_Endcap->Fill(ie);
 
    if (i > 1) {  // Take 2 first muons :-(
      TLorentzVector mu1(p1.x(), p1.y(), p1.z(), p1.mag());
      TLorentzVector mu2(p2.x(), p2.y(), p2.z(), p2.mag());
      TLorentzVector pair = mu1 + mu2;
      double Minv = pair.M();
      hSimInvM->Fill(Minv);
      if (fabs(p1.eta()) < 1.04 && fabs(p2.eta()) < 1.04)
        hSimInvM_Barrel->Fill(Minv);
      else if (fabs(p1.eta()) >= 1.04 && fabs(p2.eta()) >= 1.04)
        hSimInvM_Endcap->Fill(Minv);
      else
        hSimInvM_Overlap->Fill(Minv);
    }
 
  }  //simData
 
  // ############ Stand Alone Muon plots ###############
  if (doSAplots) {
    double SArecPt = 0.;
    double SAeta = 0.;
    double SAphi = 0.;
    int i = 0, ie = 0, ib = 0;
    double ich = 0;
 
    // Get the RecTrack collection from the event
    edm::Handle<reco::TrackCollection> staTracks;
    event.getByLabel(theSTAMuonTag, staTracks);
    numberOfSARecTracks += staTracks->size();
 
    reco::TrackCollection::const_iterator staTrack;
 
    for (staTrack = staTracks->begin(); staTrack != staTracks->end(); ++staTrack) {
      i++;
 
      SArecPt = (*staTrack).pt();
      SAeta = (*staTrack).eta();
      SAphi = (*staTrack).phi();
      ich = (*staTrack).charge();
 
      hSAPTRec->Fill(SArecPt);
      hSAPhivsEta->Fill(SAeta, SAphi);
      hSAChi2->Fill((*staTrack).chi2());
      hSANhits->Fill((*staTrack).numberOfValidHits());
      if (fabs(SAeta) < 1.04) {
        hSAPTRec_Barrel->Fill(SArecPt);
        hSAChi2_Barrel->Fill((*staTrack).chi2());
        hSANhits_Barrel->Fill((*staTrack).numberOfValidHits());
        ib++;
      } else {
        hSAPTRec_Endcap->Fill(SArecPt);
        hSAChi2_Endcap->Fill((*staTrack).chi2());
        hSANhits_Endcap->Fill((*staTrack).numberOfValidHits());
        ie++;
      }
 
      // save the muon pair
      if (i == 1)
        p1 = GlobalVector((*staTrack).momentum().x(), (*staTrack).momentum().y(), (*staTrack).momentum().z());
      if (i == 2)
        p2 = GlobalVector((*staTrack).momentum().x(), (*staTrack).momentum().y(), (*staTrack).momentum().z());
 
      if (SArecPt && theDataType == "SimData") {
        double candDeltaR = -999.0, dR;
        int iCand = 0;
        if (!simPar[0].empty()) {
          for (unsigned int iSim = 0; iSim < simPar[0].size(); iSim++) {
            dR = deltaR(SAeta, SAphi, simPar[1][iSim], simPar[2][iSim]);
            if (candDeltaR < 0 || dR < candDeltaR) {
              candDeltaR = dR;
              iCand = iSim;
            }
          }
        }
 
        double simPt = simPar[0][iCand];
        hSAPTres->Fill((SArecPt - simPt) / simPt);
        if (fabs(SAeta) < 1.04)
          hSAPTres_Barrel->Fill((SArecPt - simPt) / simPt);
        else
          hSAPTres_Endcap->Fill((SArecPt - simPt) / simPt);
 
        hSAPTDiff->Fill(SArecPt - simPt);
 
        hSAPTDiffvsEta->Fill(SAeta, SArecPt - simPt);
        hSAPTDiffvsPhi->Fill(SAphi, SArecPt - simPt);
        double ptInvRes = (ich / SArecPt - simPar[3][iCand] / simPt) / (simPar[3][iCand] / simPt);
        hSAinvPTres->Fill(ptInvRes);
 
        hSAinvPTvsEta->Fill(SAeta, ptInvRes);
        hSAinvPTvsPhi->Fill(SAphi, ptInvRes);
        hSAinvPTvsNhits->Fill((*staTrack).numberOfValidHits(), ptInvRes);
      }
 
      hSAPTvsEta->Fill(SAeta, SArecPt);
      hSAPTvsPhi->Fill(SAphi, SArecPt);
    }
 
    hSANmuons->Fill(i);
    hSANmuons_Barrel->Fill(ib);
    hSANmuons_Endcap->Fill(ie);
 
    if (i > 1) {  // Take 2 first muons :-(
      TLorentzVector mu1(p1.x(), p1.y(), p1.z(), p1.mag());
      TLorentzVector mu2(p2.x(), p2.y(), p2.z(), p2.mag());
      TLorentzVector pair = mu1 + mu2;
      double Minv = pair.M();
      hSAInvM->Fill(Minv);
      if (fabs(p1.eta()) < 1.04 && fabs(p2.eta()) < 1.04)
        hSAInvM_Barrel->Fill(Minv);
      else if (fabs(p1.eta()) >= 1.04 && fabs(p2.eta()) >= 1.04)
        hSAInvM_Endcap->Fill(Minv);
      else
        hSAInvM_Overlap->Fill(Minv);
    }  // 2 first muons
 
  }  //end doSAplots
 
  // ############### Global Muons plots ##########
 
  if (doGBplots) {
    // Get the RecTrack collection from the event
    edm::Handle<reco::TrackCollection> glbTracks;
    event.getByLabel(theGLBMuonTag, glbTracks);
    numberOfGBRecTracks += glbTracks->size();
 
    double GBrecPt = 0;
    double GBeta = 0;
    double GBphi = 0;
    double ich = 0;
    int i = 0, ie = 0, ib = 0;
 
    reco::TrackCollection::const_iterator glbTrack;
 
    for (glbTrack = glbTracks->begin(); glbTrack != glbTracks->end(); ++glbTrack) {
      i++;
 
      GBrecPt = (*glbTrack).pt();
      GBeta = (*glbTrack).eta();
      GBphi = (*glbTrack).phi();
      ich = (*glbTrack).charge();
 
      hGBPTRec->Fill(GBrecPt);
      hGBPhivsEta->Fill(GBeta, GBphi);
      hGBChi2->Fill((*glbTrack).chi2());
      hGBNhits->Fill((*glbTrack).numberOfValidHits());
      if (fabs(GBeta) < 1.04) {
        hGBPTRec_Barrel->Fill(GBrecPt);
        hGBChi2_Barrel->Fill((*glbTrack).chi2());
        hGBNhits_Barrel->Fill((*glbTrack).numberOfValidHits());
        ib++;
      } else {
        hGBPTRec_Endcap->Fill(GBrecPt);
        hGBChi2_Endcap->Fill((*glbTrack).chi2());
        hGBNhits_Endcap->Fill((*glbTrack).numberOfValidHits());
        ie++;
      }
 
      // save the muon pair
      if (i == 1)
        p1 = GlobalVector((*glbTrack).momentum().x(), (*glbTrack).momentum().y(), (*glbTrack).momentum().z());
      if (i == 2)
        p2 = GlobalVector((*glbTrack).momentum().x(), (*glbTrack).momentum().y(), (*glbTrack).momentum().z());
 
      if (GBrecPt && theDataType == "SimData") {
        double candDeltaR = -999.0, dR;
        int iCand = 0;
        if (!simPar[0].empty()) {
          for (unsigned int iSim = 0; iSim < simPar[0].size(); iSim++) {
            dR = deltaR(GBeta, GBphi, simPar[1][iSim], simPar[2][iSim]);
            if (candDeltaR < 0 || dR < candDeltaR) {
              candDeltaR = dR;
              iCand = iSim;
            }
          }
        }
 
        double simPt = simPar[0][iCand];
 
        hGBPTres->Fill((GBrecPt - simPt) / simPt);
        if (fabs(GBeta) < 1.04)
          hGBPTres_Barrel->Fill((GBrecPt - simPt) / simPt);
        else
          hGBPTres_Endcap->Fill((GBrecPt - simPt) / simPt);
 
        hGBPTDiff->Fill(GBrecPt - simPt);
 
        hGBPTDiffvsEta->Fill(GBeta, GBrecPt - simPt);
        hGBPTDiffvsPhi->Fill(GBphi, GBrecPt - simPt);
 
        double ptInvRes = (ich / GBrecPt - simPar[3][iCand] / simPt) / (simPar[3][iCand] / simPt);
        hGBinvPTres->Fill(ptInvRes);
 
        hGBinvPTvsEta->Fill(GBeta, ptInvRes);
        hGBinvPTvsPhi->Fill(GBphi, ptInvRes);
        hGBinvPTvsNhits->Fill((*glbTrack).numberOfValidHits(), ptInvRes);
      }
 
      hGBPTvsEta->Fill(GBeta, GBrecPt);
      hGBPTvsPhi->Fill(GBphi, GBrecPt);
    }
 
    hGBNmuons->Fill(i);
    hGBNmuons_Barrel->Fill(ib);
    hGBNmuons_Endcap->Fill(ie);
 
    if (i > 1) {  // Take 2 first muons :-(
      TLorentzVector mu1(p1.x(), p1.y(), p1.z(), p1.mag());
      TLorentzVector mu2(p2.x(), p2.y(), p2.z(), p2.mag());
      TLorentzVector pair = mu1 + mu2;
      double Minv = pair.M();
      hGBInvM->Fill(Minv);
      if (fabs(p1.eta()) < 1.04 && fabs(p2.eta()) < 1.04)
        hGBInvM_Barrel->Fill(Minv);
      else if (fabs(p1.eta()) >= 1.04 && fabs(p2.eta()) >= 1.04)
        hGBInvM_Endcap->Fill(Minv);
      else
        hGBInvM_Overlap->Fill(Minv);
    }
 
  }  //end doGBplots
 
  // ############    Residual plots ###################
 
  if (doResplots) {
    const MagneticField *theMGField = &eventSetup.getData(magFieldToken_);
    edm::ESHandle<GlobalTrackingGeometry> theTrackingGeometry = eventSetup.getHandle(trackingGeometryToken_);
 
    // Get the RecTrack collection from the event
    edm::Handle<reco::TrackCollection> staTracks;
    event.getByLabel(theSTAMuonTag, staTracks);
 
    // Get the 4D DTSegments
    edm::Handle<DTRecSegment4DCollection> all4DSegmentsDT;
    event.getByLabel(theRecHits4DTagDT, all4DSegmentsDT);
    DTRecSegment4DCollection::const_iterator segmentDT;
 
    // Get the 4D CSCSegments
    edm::Handle<CSCSegmentCollection> all4DSegmentsCSC;
    event.getByLabel(theRecHits4DTagCSC, all4DSegmentsCSC);
    CSCSegmentCollection::const_iterator segmentCSC;
 
    //Vectors used to perform the matching between Segments and hits from Track
    intDVector indexCollectionDT;
    intDVector indexCollectionCSC;
 
    /*    std::cout << "<MuonAlignmentAnalyzer> List of DTSegments found in Local Reconstruction" << std::endl;
      std::cout << "Number: " << all4DSegmentsDT->size() << std::endl;
      for (segmentDT = all4DSegmentsDT->begin(); segmentDT != all4DSegmentsDT->end(); ++segmentDT){
      const GeomDet* geomDet = theTrackingGeometry->idToDet((*segmentDT).geographicalId());
      std::cout << "<MuonAlignmentAnalyzer> " << geomDet->toGlobal((*segmentDT).localPosition()) << std::endl;
      std::cout << "<MuonAlignmentAnalyzer> Local " << (*segmentDT).localPosition() << std::endl;
      }
      std::cout << "<MuonAlignmentAnalyzer> List of CSCSegments found in Local Reconstruction" << std::endl;
      for (segmentCSC = all4DSegmentsCSC->begin(); segmentCSC != all4DSegmentsCSC->end(); ++segmentCSC){
      const GeomDet* geomDet = theTrackingGeometry->idToDet((*segmentCSC).geographicalId());
      std::cout << "<MuonAlignmentAnalyzer>" << geomDet->toGlobal((*segmentCSC).localPosition()) << std::endl;
      }
*/
    thePropagator = new SteppingHelixPropagator(theMGField, alongMomentum);
 
    reco::TrackCollection::const_iterator staTrack;
    for (staTrack = staTracks->begin(); staTrack != staTracks->end(); ++staTrack) {
      int countPoints = 0;
 
      reco::TransientTrack track(*staTrack, theMGField, theTrackingGeometry);
 
      if (staTrack->numberOfValidHits() > (min1DTrackRecHitSize - 1)) {
        RecHitVector my4DTrack = this->doMatching(
            *staTrack, all4DSegmentsDT, all4DSegmentsCSC, &indexCollectionDT, &indexCollectionCSC, theTrackingGeometry);
 
        //cut in number of segments
 
        if (my4DTrack.size() > (min4DTrackSegmentSize - 1)) {
          // start propagation
          //    TrajectoryStateOnSurface innerTSOS = track.impactPointState();
          TrajectoryStateOnSurface innerTSOS = track.innermostMeasurementState();
 
          //If the state is valid
          if (innerTSOS.isValid()) {
            //Loop over Associated segments
            for (RecHitVector::iterator rechit = my4DTrack.begin(); rechit != my4DTrack.end(); ++rechit) {
              const GeomDet *geomDet = theTrackingGeometry->idToDet((*rechit)->geographicalId());
              //Otherwise the propagator could throw an exception
              const Plane *pDest = dynamic_cast<const Plane *>(&geomDet->surface());
              const Cylinder *cDest = dynamic_cast<const Cylinder *>(&geomDet->surface());
 
              if (pDest != nullptr || cDest != nullptr) {  //Donde antes iba el try
 
                TrajectoryStateOnSurface destiny =
                    thePropagator->propagate(*(innerTSOS.freeState()), geomDet->surface());
 
                if (!destiny.isValid() || !destiny.hasError())
                  continue;
 
                /*      std::cout << "<MuonAlignmentAnalyzer> Segment: " << geomDet->toGlobal((*rechit)->localPosition()) << std::endl;
  std::cout << "<MuonAlignmentAnalyzer> Segment local: " << (*rechit)->localPosition() << std::endl;
  std::cout << "<MuonAlignmentAnalyzer> Predicted: " << destiny.freeState()->position() << std::endl;
  std::cout << "<MuonAlignmentAnalyzer> Predicted local: " << destiny.localPosition() << std::endl;
*/
                const long rawId = (*rechit)->geographicalId().rawId();
                int position = -1;
                bool newDetector = true;
                //Loop over the DetectorCollection to see if the detector is new and requires a new entry
                for (std::vector<long>::iterator myIds = detectorCollection.begin(); myIds != detectorCollection.end();
                     myIds++) {
                  ++position;
                  //If matches newDetector = false
                  if (*myIds == rawId) {
                    newDetector = false;
                    break;
                  }
                }
 
                DetId myDet(rawId);
                int det = myDet.subdetId();
                int wheel = 0, station = 0, sector = 0;
                int endcap = 0, ring = 0, chamber = 0;
 
                double residualGlobalRPhi = 0, residualGlobalPhi = 0, residualGlobalR = 0, residualGlobalTheta = 0,
                       residualGlobalZ = 0;
                double residualLocalX = 0, residualLocalPhi = 0, residualLocalY = 0, residualLocalTheta = 0;
 
                // Fill generic histograms
                //If it's a DT
                if (det == 1) {
                  DTChamberId myChamber(rawId);
                  wheel = myChamber.wheel();
                  station = myChamber.station();
                  sector = myChamber.sector();
 
                  //global
                  residualGlobalRPhi =
                      geomDet->toGlobal((*rechit)->localPosition()).perp() *
                          geomDet->toGlobal((*rechit)->localPosition()).barePhi() -
                      destiny.freeState()->position().perp() * destiny.freeState()->position().barePhi();
 
                  //local
                  residualLocalX = (*rechit)->localPosition().x() - destiny.localPosition().x();
 
                  //global
                  residualGlobalPhi = geomDet->toGlobal(((RecSegment *)(*rechit))->localDirection()).barePhi() -
                                      destiny.globalDirection().barePhi();
 
                  //local
                  residualLocalPhi = atan2(((RecSegment *)(*rechit))->localDirection().z(),
                                           ((RecSegment *)(*rechit))->localDirection().x()) -
                                     atan2(destiny.localDirection().z(), destiny.localDirection().x());
 
                  hResidualGlobalRPhiDT->Fill(residualGlobalRPhi);
                  hResidualGlobalPhiDT->Fill(residualGlobalPhi);
                  hResidualLocalXDT->Fill(residualLocalX);
                  hResidualLocalPhiDT->Fill(residualLocalPhi);
 
                  if (station != 4) {
                    //global
                    residualGlobalZ =
                        geomDet->toGlobal((*rechit)->localPosition()).z() - destiny.freeState()->position().z();
 
                    //local
                    residualLocalY = (*rechit)->localPosition().y() - destiny.localPosition().y();
 
                    //global
                    residualGlobalTheta = geomDet->toGlobal(((RecSegment *)(*rechit))->localDirection()).bareTheta() -
                                          destiny.globalDirection().bareTheta();
 
                    //local
                    residualLocalTheta = atan2(((RecSegment *)(*rechit))->localDirection().z(),
                                               ((RecSegment *)(*rechit))->localDirection().y()) -
                                         atan2(destiny.localDirection().z(), destiny.localDirection().y());
 
                    hResidualGlobalThetaDT->Fill(residualGlobalTheta);
                    hResidualGlobalZDT->Fill(residualGlobalZ);
                    hResidualLocalThetaDT->Fill(residualLocalTheta);
                    hResidualLocalYDT->Fill(residualLocalY);
                  }
 
                  int index = wheel + 2;
                  hResidualGlobalRPhiDT_W[index]->Fill(residualGlobalRPhi);
                  hResidualGlobalPhiDT_W[index]->Fill(residualGlobalPhi);
                  hResidualLocalXDT_W[index]->Fill(residualLocalX);
                  hResidualLocalPhiDT_W[index]->Fill(residualLocalPhi);
                  if (station != 4) {
                    hResidualGlobalThetaDT_W[index]->Fill(residualGlobalTheta);
                    hResidualGlobalZDT_W[index]->Fill(residualGlobalZ);
                    hResidualLocalThetaDT_W[index]->Fill(residualLocalTheta);
                    hResidualLocalYDT_W[index]->Fill(residualLocalY);
                  }
 
                  index = wheel * 4 + station + 7;
                  hResidualGlobalRPhiDT_MB[index]->Fill(residualGlobalRPhi);
                  hResidualGlobalPhiDT_MB[index]->Fill(residualGlobalPhi);
                  hResidualLocalXDT_MB[index]->Fill(residualLocalX);
                  hResidualLocalPhiDT_MB[index]->Fill(residualLocalPhi);
 
                  if (station != 4) {
                    hResidualGlobalThetaDT_MB[index]->Fill(residualGlobalTheta);
                    hResidualGlobalZDT_MB[index]->Fill(residualGlobalZ);
                    hResidualLocalThetaDT_MB[index]->Fill(residualLocalTheta);
                    hResidualLocalYDT_MB[index]->Fill(residualLocalY);
                  }
                } else if (det == 2) {
                  CSCDetId myChamber(rawId);
                  endcap = myChamber.endcap();
                  station = myChamber.station();
                  if (endcap == 2)
                    station = -station;
                  ring = myChamber.ring();
                  chamber = myChamber.chamber();
 
                  //global
                  residualGlobalRPhi =
                      geomDet->toGlobal((*rechit)->localPosition()).perp() *
                          geomDet->toGlobal((*rechit)->localPosition()).barePhi() -
                      destiny.freeState()->position().perp() * destiny.freeState()->position().barePhi();
 
                  //local
                  residualLocalX = (*rechit)->localPosition().x() - destiny.localPosition().x();
 
                  //global
                  residualGlobalR =
                      geomDet->toGlobal((*rechit)->localPosition()).perp() - destiny.freeState()->position().perp();
 
                  //local
                  residualLocalY = (*rechit)->localPosition().y() - destiny.localPosition().y();
 
                  //global
                  residualGlobalPhi = geomDet->toGlobal(((RecSegment *)(*rechit))->localDirection()).barePhi() -
                                      destiny.globalDirection().barePhi();
 
                  //local
                  residualLocalPhi = atan2(((RecSegment *)(*rechit))->localDirection().y(),
                                           ((RecSegment *)(*rechit))->localDirection().x()) -
                                     atan2(destiny.localDirection().y(), destiny.localDirection().x());
 
                  //global
                  residualGlobalTheta = geomDet->toGlobal(((RecSegment *)(*rechit))->localDirection()).bareTheta() -
                                        destiny.globalDirection().bareTheta();
 
                  //local
                  residualLocalTheta = atan2(((RecSegment *)(*rechit))->localDirection().y(),
                                             ((RecSegment *)(*rechit))->localDirection().z()) -
                                       atan2(destiny.localDirection().y(), destiny.localDirection().z());
 
                  hResidualGlobalRPhiCSC->Fill(residualGlobalRPhi);
                  hResidualGlobalPhiCSC->Fill(residualGlobalPhi);
                  hResidualGlobalThetaCSC->Fill(residualGlobalTheta);
                  hResidualGlobalRCSC->Fill(residualGlobalR);
                  hResidualLocalXCSC->Fill(residualLocalX);
                  hResidualLocalPhiCSC->Fill(residualLocalPhi);
                  hResidualLocalThetaCSC->Fill(residualLocalTheta);
                  hResidualLocalYCSC->Fill(residualLocalY);
 
                  int index = 2 * station + ring + 7;
                  if (station == -1) {
                    index = 5 + ring;
                    if (ring == 4)
                      index = 6;
                  }
                  if (station == 1) {
                    index = 8 + ring;
                    if (ring == 4)
                      index = 9;
                  }
                  hResidualGlobalRPhiCSC_ME[index]->Fill(residualGlobalRPhi);
                  hResidualGlobalPhiCSC_ME[index]->Fill(residualGlobalPhi);
                  hResidualGlobalThetaCSC_ME[index]->Fill(residualGlobalTheta);
                  hResidualGlobalRCSC_ME[index]->Fill(residualGlobalR);
                  hResidualLocalXCSC_ME[index]->Fill(residualLocalX);
                  hResidualLocalPhiCSC_ME[index]->Fill(residualLocalPhi);
                  hResidualLocalThetaCSC_ME[index]->Fill(residualLocalTheta);
                  hResidualLocalYCSC_ME[index]->Fill(residualLocalY);
 
                } else {
                  residualGlobalRPhi = 0, residualGlobalPhi = 0, residualGlobalR = 0, residualGlobalTheta = 0,
                  residualGlobalZ = 0;
                  residualLocalX = 0, residualLocalPhi = 0, residualLocalY = 0, residualLocalTheta = 0;
                }
                // Fill individual chamber histograms
                if (newDetector) {
                  //Create an RawIdDetector, fill it and push it into the collection
                  detectorCollection.push_back(rawId);
 
                  //This piece of code calculates the range of the residuals
                  double rangeX = 3.0, rangeY = 5.;
                  switch (abs(station)) {
                    case 1: {
                      rangeX = resLocalXRangeStation1;
                      rangeY = resLocalYRangeStation1;
                    } break;
                    case 2: {
                      rangeX = resLocalXRangeStation2;
                      rangeY = resLocalYRangeStation2;
                    } break;
                    case 3: {
                      rangeX = resLocalXRangeStation3;
                      rangeY = resLocalYRangeStation3;
                    } break;
                    case 4: {
                      rangeX = resLocalXRangeStation4;
                      rangeY = resLocalYRangeStation4;
                    } break;
                    default:
                      break;
                  }
 
                  //create new histograms
 
                  char nameOfHistoLocalX[50];
                  char nameOfHistoLocalTheta[50];
                  char nameOfHistoLocalY[50];
                  char nameOfHistoLocalPhi[50];
                  char nameOfHistoGlobalRPhi[50];
                  char nameOfHistoGlobalTheta[50];
                  char nameOfHistoGlobalR[50];
                  char nameOfHistoGlobalPhi[50];
                  char nameOfHistoGlobalZ[50];
 
                  if (det == 1) {  // DT
                    snprintf(nameOfHistoLocalX,
                             sizeof(nameOfHistoLocalX),
                             "ResidualLocalX_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoLocalPhi,
                             sizeof(nameOfHistoLocalPhi),
                             "ResidualLocalPhi_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoGlobalRPhi,
                             sizeof(nameOfHistoGlobalRPhi),
                             "ResidualGlobalRPhi_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoGlobalPhi,
                             sizeof(nameOfHistoGlobalPhi),
                             "ResidualGlobalPhi_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoLocalTheta,
                             sizeof(nameOfHistoLocalTheta),
                             "ResidualLocalTheta_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoLocalY,
                             sizeof(nameOfHistoLocalY),
                             "ResidualLocalY_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    TH1F *histoLocalY = fs->make<TH1F>(nameOfHistoLocalY, nameOfHistoLocalY, nbins, -rangeY, rangeY);
                    unitsLocalY.push_back(histoLocalY);
                    snprintf(nameOfHistoGlobalTheta,
                             sizeof(nameOfHistoGlobalTheta),
                             "ResidualGlobalTheta_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    snprintf(nameOfHistoGlobalZ,
                             sizeof(nameOfHistoGlobalZ),
                             "ResidualGlobalZ_W%dMB%1dS%1d",
                             wheel,
                             station,
                             sector);
                    TH1F *histoGlobalZ = fs->make<TH1F>(nameOfHistoGlobalZ, nameOfHistoGlobalZ, nbins, -rangeY, rangeY);
                    unitsGlobalRZ.push_back(histoGlobalZ);
 
                  } else if (det == 2) {  //CSC
                    snprintf(nameOfHistoLocalX,
                             sizeof(nameOfHistoLocalX),
                             "ResidualLocalX_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoLocalPhi,
                             sizeof(nameOfHistoLocalPhi),
                             "ResidualLocalPhi_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoLocalTheta,
                             sizeof(nameOfHistoLocalTheta),
                             "ResidualLocalTheta_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoLocalY,
                             sizeof(nameOfHistoLocalY),
                             "ResidualLocalY_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    TH1F *histoLocalY = fs->make<TH1F>(nameOfHistoLocalY, nameOfHistoLocalY, nbins, -rangeY, rangeY);
                    unitsLocalY.push_back(histoLocalY);
                    snprintf(nameOfHistoGlobalRPhi,
                             sizeof(nameOfHistoGlobalRPhi),
                             "ResidualGlobalRPhi_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoGlobalPhi,
                             sizeof(nameOfHistoGlobalPhi),
                             "ResidualGlobalPhi_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoGlobalTheta,
                             sizeof(nameOfHistoGlobalTheta),
                             "ResidualGlobalTheta_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    snprintf(nameOfHistoGlobalR,
                             sizeof(nameOfHistoGlobalR),
                             "ResidualGlobalR_ME%dR%1dC%1d",
                             station,
                             ring,
                             chamber);
                    TH1F *histoGlobalR = fs->make<TH1F>(nameOfHistoGlobalR, nameOfHistoGlobalR, nbins, -rangeY, rangeY);
                    unitsGlobalRZ.push_back(histoGlobalR);
                  }
 
                  // Common histos to DT and CSC
                  TH1F *histoLocalX = fs->make<TH1F>(nameOfHistoLocalX, nameOfHistoLocalX, nbins, -rangeX, rangeX);
                  TH1F *histoGlobalRPhi =
                      fs->make<TH1F>(nameOfHistoGlobalRPhi, nameOfHistoGlobalRPhi, nbins, -rangeX, rangeX);
                  TH1F *histoLocalPhi =
                      fs->make<TH1F>(nameOfHistoLocalPhi, nameOfHistoLocalPhi, nbins, -resPhiRange, resPhiRange);
                  TH1F *histoGlobalPhi =
                      fs->make<TH1F>(nameOfHistoGlobalPhi, nameOfHistoGlobalPhi, nbins, -resPhiRange, resPhiRange);
                  TH1F *histoGlobalTheta = fs->make<TH1F>(
                      nameOfHistoGlobalTheta, nameOfHistoGlobalTheta, nbins, -resThetaRange, resThetaRange);
                  TH1F *histoLocalTheta = fs->make<TH1F>(
                      nameOfHistoLocalTheta, nameOfHistoLocalTheta, nbins, -resThetaRange, resThetaRange);
 
                  histoLocalX->Fill(residualLocalX);
                  histoLocalPhi->Fill(residualLocalPhi);
                  histoLocalTheta->Fill(residualLocalTheta);
                  histoGlobalRPhi->Fill(residualGlobalRPhi);
                  histoGlobalPhi->Fill(residualGlobalPhi);
                  histoGlobalTheta->Fill(residualGlobalTheta);
                  //Push them into their respective vectors
                  unitsLocalX.push_back(histoLocalX);
                  unitsLocalPhi.push_back(histoLocalPhi);
                  unitsLocalTheta.push_back(histoLocalTheta);
                  unitsGlobalRPhi.push_back(histoGlobalRPhi);
                  unitsGlobalPhi.push_back(histoGlobalPhi);
                  unitsGlobalTheta.push_back(histoGlobalTheta);
 
                }  // new detector
                else {
                  //If the detector was not new, just fill the histogram
                  unitsLocalX.at(position)->Fill(residualLocalX);
                  unitsLocalPhi.at(position)->Fill(residualLocalPhi);
                  unitsLocalTheta.at(position)->Fill(residualLocalTheta);
                  unitsGlobalRPhi.at(position)->Fill(residualGlobalRPhi);
                  unitsGlobalPhi.at(position)->Fill(residualGlobalPhi);
                  unitsGlobalTheta.at(position)->Fill(residualGlobalTheta);
                  if (det == 1) {
                    unitsLocalY.at(position)->Fill(residualLocalY);
                    unitsGlobalRZ.at(position)->Fill(residualGlobalZ);
                  } else if (det == 2) {
                    unitsLocalY.at(position)->Fill(residualLocalY);
                    unitsGlobalRZ.at(position)->Fill(residualGlobalR);
                  }
                }
 
                countPoints++;
 
                innerTSOS = destiny;
 
              } else {
                edm::LogError("MuonAlignmentAnalyzer") << " Error!! Exception in propagator catched" << std::endl;
                continue;
              }
 
            }  //loop over my4DTrack
          }    //TSOS was valid
 
        }  // cut in at least 4 segments
 
      }  //end cut in RecHitsSize>36
      numberOfHits = numberOfHits + countPoints;
    }  //loop over STAtracks
 
    delete thePropagator;
 
  }  //end doResplots
}

References funct::abs(), alongMomentum, PV3DBase< T, PVType, FrameType >::barePhi(), barePhi(), PV3DBase< T, PVType, FrameType >::bareTheta(), relativeConstraints::chamber, CSCDetId::chamber(), PbPb_ZMuSkimMuonDPG_cff::deltaR, detectorCollection, doGBplots, doMatching(), doResplots, doSAplots, HGC3DClusterGenMatchSelector_cfi::dR, relativeConstraints::empty, CSCDetId::endcap(), makeMuonMisalignmentScenario::endcap, TrajectoryStateOnSurface::freeState(), fs, edm::EventSetup::getData(), edm::EventSetup::getHandle(), TrajectoryStateOnSurface::globalDirection(), TrajectoryStateOnSurface::hasError(), hGBChi2, hGBChi2_Barrel, hGBChi2_Endcap, hGBInvM, hGBInvM_Barrel, hGBInvM_Endcap, hGBInvM_Overlap, hGBinvPTres, hGBinvPTvsEta, hGBinvPTvsNhits, hGBinvPTvsPhi, hGBNhits, hGBNhits_Barrel, hGBNhits_Endcap, hGBNmuons, hGBNmuons_Barrel, hGBNmuons_Endcap, hGBPhivsEta, hGBPTDiff, hGBPTDiffvsEta, hGBPTDiffvsPhi, hGBPTRec, hGBPTRec_Barrel, hGBPTRec_Endcap, hGBPTres, hGBPTres_Barrel, hGBPTres_Endcap, hGBPTvsEta, hGBPTvsPhi, hResidualGlobalPhiCSC, hResidualGlobalPhiCSC_ME, hResidualGlobalPhiDT, hResidualGlobalPhiDT_MB, hResidualGlobalPhiDT_W, hResidualGlobalRCSC, hResidualGlobalRCSC_ME, hResidualGlobalRPhiCSC, hResidualGlobalRPhiCSC_ME, hResidualGlobalRPhiDT, hResidualGlobalRPhiDT_MB, hResidualGlobalRPhiDT_W, hResidualGlobalThetaCSC, hResidualGlobalThetaCSC_ME, hResidualGlobalThetaDT, hResidualGlobalThetaDT_MB, hResidualGlobalThetaDT_W, hResidualGlobalZDT, hResidualGlobalZDT_MB, hResidualGlobalZDT_W, hResidualLocalPhiCSC, hResidualLocalPhiCSC_ME, hResidualLocalPhiDT, hResidualLocalPhiDT_MB, hResidualLocalPhiDT_W, hResidualLocalThetaCSC, hResidualLocalThetaCSC_ME, hResidualLocalThetaDT, hResidualLocalThetaDT_MB, hResidualLocalThetaDT_W, hResidualLocalXCSC, hResidualLocalXCSC_ME, hResidualLocalXDT, hResidualLocalXDT_MB, hResidualLocalXDT_W, hResidualLocalYCSC, hResidualLocalYCSC_ME, hResidualLocalYDT, hResidualLocalYDT_MB, hResidualLocalYDT_W, hSAChi2, hSAChi2_Barrel, hSAChi2_Endcap, hSAInvM, hSAInvM_Barrel, hSAInvM_Endcap, hSAInvM_Overlap, hSAinvPTres, hSAinvPTvsEta, hSAinvPTvsNhits, hSAinvPTvsPhi, hSANhits, hSANhits_Barrel, hSANhits_Endcap, hSANmuons, hSANmuons_Barrel, hSANmuons_Endcap, hSAPhivsEta, hSAPTDiff, hSAPTDiffvsEta, hSAPTDiffvsPhi, hSAPTRec, hSAPTRec_Barrel, hSAPTRec_Endcap, hSAPTres, hSAPTres_Barrel, hSAPTres_Endcap, hSAPTvsEta, hSAPTvsPhi, hSimInvM, hSimInvM_Barrel, hSimInvM_Endcap, hSimInvM_Overlap, hSimNmuons, hSimNmuons_Barrel, hSimNmuons_Endcap, hSimPhivsEta, hSimPT, hSimPT_Barrel, hSimPT_Endcap, hSimPTvsEta, hSimPTvsPhi, mps_fire::i, cuy::ib, GlobalTrackingGeometry::idToDet(), TrajectoryStateOnSurface::isValid(), TrajectoryStateOnSurface::localDirection(), TrajectoryStateOnSurface::localPosition(), magFieldToken_, TFileService::make(), min1DTrackRecHitSize, min4DTrackSegmentSize, nbins, numberOfGBRecTracks, numberOfHits, numberOfSARecTracks, numberOfSimTracks, p1, p2, PV3DBase< T, PVType, FrameType >::perp(), perp(), FreeTrajectoryState::position(), position, Propagator::propagate(), resLocalXRangeStation1, resLocalXRangeStation2, resLocalXRangeStation3, resLocalXRangeStation4, resLocalYRangeStation1, resLocalYRangeStation2, resLocalYRangeStation3, resLocalYRangeStation4, resPhiRange, resThetaRange, CSCDetId::ring(), relativeConstraints::ring, DTChamberId::sector(), muonSimHitMatcherPSet::simTrack, TrackCandidateProducer_cfi::simTracks, DTChamberId::station(), relativeConstraints::station, CSCDetId::station(), muonTagProbeFilters_cff::staTracks, SteppingHelixPropagator_cfi::SteppingHelixPropagator, DetId::subdetId(), GeomDet::surface(), theDataType, theGLBMuonTag, thePropagator, theRecHits4DTagCSC, theRecHits4DTagDT, theSTAMuonTag, GeomDet::toGlobal(), HLT_FULL_cff::track, trackingGeometryToken_, unitsGlobalPhi, unitsGlobalRPhi, unitsGlobalRZ, unitsGlobalTheta, unitsLocalPhi, unitsLocalTheta, unitsLocalX, unitsLocalY, DTChamberId::wheel(), makeMuonMisalignmentScenario::wheel, x, PV3DBase< T, PVType, FrameType >::x(), y, PV3DBase< T, PVType, FrameType >::y(), z, and PV3DBase< T, PVType, FrameType >::z().

beginJob()

void MuonAlignmentAnalyzer::beginJob ( void  )

overridevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 240 of file MuonAlignmentAnalyzer.cc.

                                     {
  //  eventSetup.get<IdealMagneticFieldRecord>().get(theMGField);
 
  //Create the propagator
  //  if(doResplots)  thePropagator = new SteppingHelixPropagator(&*theMGField, alongMomentum);
 
  int nBinsPt = (int)fabs(ptRangeMax - ptRangeMin);
  int nBinsMass = (int)fabs(invMassRangeMax - invMassRangeMin);
 
  // Define and book histograms for SA and GB muon quantities/objects
 
  if (doGBplots) {
    hGBNmuons = fs->make<TH1F>("GBNmuons", "Nmuons", 10, 0, 10);
    hGBNmuons_Barrel = fs->make<TH1F>("GBNmuons_Barrel", "Nmuons", 10, 0, 10);
    hGBNmuons_Endcap = fs->make<TH1F>("GBNmuons_Endcap", "Nmuons", 10, 0, 10);
    hGBNhits = fs->make<TH1F>("GBNhits", "Nhits", 100, 0, 100);
    hGBNhits_Barrel = fs->make<TH1F>("GBNhits_Barrel", "Nhits", 100, 0, 100);
    hGBNhits_Endcap = fs->make<TH1F>("GBNhits_Endcap", "Nhits", 100, 0, 100);
    hGBPTRec = fs->make<TH1F>("GBpTRec", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hGBPTRec_Barrel = fs->make<TH1F>("GBpTRec_Barrel", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hGBPTRec_Endcap = fs->make<TH1F>("GBpTRec_Endcap", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hGBPTvsEta = fs->make<TH2F>("GBPTvsEta", "p_{T}^{rec} VS #eta", 100, -2.5, 2.5, nBinsPt, ptRangeMin, ptRangeMax);
    hGBPTvsPhi =
        fs->make<TH2F>("GBPTvsPhi", "p_{T}^{rec} VS #phi", 100, -3.1416, 3.1416, nBinsPt, ptRangeMin, ptRangeMax);
    hGBPhivsEta = fs->make<TH2F>("GBPhivsEta", "#phi VS #eta", 100, -2.5, 2.5, 100, -3.1416, 3.1416);
 
    if (theDataType == "SimData") {
      hGBPTDiff = fs->make<TH1F>("GBpTDiff", "p_{T}^{rec} - p_{T}^{gen} ", 250, -120, 120);
      hGBPTDiffvsEta =
          fs->make<TH2F>("GBPTDiffvsEta", "p_{T}^{rec} - p_{T}^{gen} VS #eta", 100, -2.5, 2.5, 250, -120, 120);
      hGBPTDiffvsPhi =
          fs->make<TH2F>("GBPTDiffvsPhi", "p_{T}^{rec} - p_{T}^{gen} VS #phi", 100, -3.1416, 3.1416, 250, -120, 120);
      hGBPTres = fs->make<TH1F>("GBpTRes", "pT Resolution", 100, -2, 2);
      hGBPTres_Barrel = fs->make<TH1F>("GBpTRes_Barrel", "pT Resolution", 100, -2, 2);
      hGBPTres_Endcap = fs->make<TH1F>("GBpTRes_Endcap", "pT Resolution", 100, -2, 2);
      hGBinvPTres = fs->make<TH1F>("GBinvPTRes", "#sigma (q/p_{T}) Resolution", 100, -2, 2);
      hGBinvPTvsEta = fs->make<TH2F>("GBinvPTvsEta", "#sigma (q/p_{T}) VS #eta", 100, -2.5, 2.5, 100, -2, 2);
      hGBinvPTvsPhi = fs->make<TH2F>("GBinvPTvsPhi", "#sigma (q/p_{T}) VS #phi", 100, -3.1416, 3.1416, 100, -2, 2);
      hGBinvPTvsNhits = fs->make<TH2F>("GBinvPTvsNhits", "#sigma (q/p_{T}) VS Nhits", 100, 0, 100, 100, -2, 2);
    }
 
    hGBChi2 = fs->make<TH1F>("GBChi2", "Chi2", 200, 0, 200);
    hGBChi2_Barrel = fs->make<TH1F>("GBChi2_Barrel", "Chi2", 200, 0, 200);
    hGBChi2_Endcap = fs->make<TH1F>("GBChi2_Endcap ", "Chi2", 200, 0, 200);
    hGBInvM = fs->make<TH1F>("GBInvM", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hGBInvM_Barrel = fs->make<TH1F>("GBInvM_Barrel", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hGBInvM_Endcap = fs->make<TH1F>("GBInvM_Endcap ", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hGBInvM_Overlap = fs->make<TH1F>("GBInvM_Overlap", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
  }
 
  if (doSAplots) {
    hSANmuons = fs->make<TH1F>("SANmuons", "Nmuons", 10, 0, 10);
    hSANmuons_Barrel = fs->make<TH1F>("SANmuons_Barrel", "Nmuons", 10, 0, 10);
    hSANmuons_Endcap = fs->make<TH1F>("SANmuons_Endcap", "Nmuons", 10, 0, 10);
    hSANhits = fs->make<TH1F>("SANhits", "Nhits", 100, 0, 100);
    hSANhits_Barrel = fs->make<TH1F>("SANhits_Barrel", "Nhits", 100, 0, 100);
    hSANhits_Endcap = fs->make<TH1F>("SANhits_Endcap", "Nhits", 100, 0, 100);
    hSAPTRec = fs->make<TH1F>("SApTRec", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hSAPTRec_Barrel = fs->make<TH1F>("SApTRec_Barrel", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hSAPTRec_Endcap = fs->make<TH1F>("SApTRec_Endcap", "p_{T}^{rec}", nBinsPt, ptRangeMin, ptRangeMax);
    hSAPTvsEta = fs->make<TH2F>("SAPTvsEta", "p_{T}^{rec} VS #eta", 100, -2.5, 2.5, nBinsPt, ptRangeMin, ptRangeMax);
    hSAPTvsPhi =
        fs->make<TH2F>("SAPTvsPhi", "p_{T}^{rec} VS #phi", 100, -3.1416, 3.1416, nBinsPt, ptRangeMin, ptRangeMax);
    hSAPhivsEta = fs->make<TH2F>("SAPhivsEta", "#phi VS #eta", 100, -2.5, 2.5, 100, -3.1416, 3.1416);
 
    if (theDataType == "SimData") {
      hSAPTDiff = fs->make<TH1F>("SApTDiff", "p_{T}^{rec} - p_{T}^{gen} ", 250, -120, 120);
      hSAPTDiffvsEta =
          fs->make<TH2F>("SAPTDiffvsEta", "p_{T}^{rec} - p_{T}^{gen} VS #eta", 100, -2.5, 2.5, 250, -120, 120);
      hSAPTDiffvsPhi =
          fs->make<TH2F>("SAPTDiffvsPhi", "p_{T}^{rec} - p_{T}^{gen} VS #phi", 100, -3.1416, 3.1416, 250, -120, 120);
      hSAPTres = fs->make<TH1F>("SApTRes", "pT Resolution", 100, -2, 2);
      hSAPTres_Barrel = fs->make<TH1F>("SApTRes_Barrel", "pT Resolution", 100, -2, 2);
      hSAPTres_Endcap = fs->make<TH1F>("SApTRes_Endcap", "pT Resolution", 100, -2, 2);
      hSAinvPTres = fs->make<TH1F>("SAinvPTRes", "1/pT Resolution", 100, -2, 2);
 
      hSAinvPTvsEta = fs->make<TH2F>("SAinvPTvsEta", "#sigma (q/p_{T}) VS #eta", 100, -2.5, 2.5, 100, -2, 2);
      hSAinvPTvsPhi = fs->make<TH2F>("SAinvPTvsPhi", "#sigma (q/p_{T}) VS #phi", 100, -3.1416, 3.1416, 100, -2, 2);
      hSAinvPTvsNhits = fs->make<TH2F>("SAinvPTvsNhits", "#sigma (q/p_{T}) VS Nhits", 100, 0, 100, 100, -2, 2);
    }
    hSAInvM = fs->make<TH1F>("SAInvM", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSAInvM_Barrel = fs->make<TH1F>("SAInvM_Barrel", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSAInvM_Endcap = fs->make<TH1F>("SAInvM_Endcap", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSAInvM_Overlap = fs->make<TH1F>("SAInvM_Overlap", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSAChi2 = fs->make<TH1F>("SAChi2", "Chi2", 200, 0, 200);
    hSAChi2_Barrel = fs->make<TH1F>("SAChi2_Barrel", "Chi2", 200, 0, 200);
    hSAChi2_Endcap = fs->make<TH1F>("SAChi2_Endcap", "Chi2", 200, 0, 200);
  }
 
  if (theDataType == "SimData") {
    hSimNmuons = fs->make<TH1F>("SimNmuons", "Nmuons", 10, 0, 10);
    hSimNmuons_Barrel = fs->make<TH1F>("SimNmuons_Barrel", "Nmuons", 10, 0, 10);
    hSimNmuons_Endcap = fs->make<TH1F>("SimNmuons_Endcap", "Nmuons", 10, 0, 10);
    hSimPT = fs->make<TH1F>("SimPT", "p_{T}^{gen} ", nBinsPt, ptRangeMin, ptRangeMax);
    hSimPT_Barrel = fs->make<TH1F>("SimPT_Barrel", "p_{T}^{gen} ", nBinsPt, ptRangeMin, ptRangeMax);
    hSimPT_Endcap = fs->make<TH1F>("SimPT_Endcap", "p_{T}^{gen} ", nBinsPt, ptRangeMin, ptRangeMax);
    hSimPTvsEta = fs->make<TH2F>("SimPTvsEta", "p_{T}^{gen} VS #eta", 100, -2.5, 2.5, nBinsPt, ptRangeMin, ptRangeMax);
    hSimPTvsPhi =
        fs->make<TH2F>("SimPTvsPhi", "p_{T}^{gen} VS #phi", 100, -3.1416, 3.1416, nBinsPt, ptRangeMin, ptRangeMax);
    hSimPhivsEta = fs->make<TH2F>("SimPhivsEta", "#phi VS #eta", 100, -2.5, 2.5, 100, -3.1416, 3.1416);
    hSimInvM = fs->make<TH1F>("SimInvM", "M_{inv}^{gen} ", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSimInvM_Barrel = fs->make<TH1F>("SimInvM_Barrel", "M_{inv}^{rec}", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSimInvM_Endcap = fs->make<TH1F>("SimInvM_Endcap", "M_{inv}^{gen} ", nBinsMass, invMassRangeMin, invMassRangeMax);
    hSimInvM_Overlap = fs->make<TH1F>("SimInvM_Overlap", "M_{inv}^{gen} ", nBinsMass, invMassRangeMin, invMassRangeMax);
  }
 
  if (doResplots) {
    // All DT and CSC chambers
    hResidualLocalXDT = fs->make<TH1F>("hResidualLocalXDT", "hResidualLocalXDT", 200, -10, 10);
    hResidualLocalPhiDT = fs->make<TH1F>("hResidualLocalPhiDT", "hResidualLocalPhiDT", 100, -1, 1);
    hResidualLocalThetaDT = fs->make<TH1F>("hResidualLocalThetaDT", "hResidualLocalThetaDT", 100, -1, 1);
    hResidualLocalYDT = fs->make<TH1F>("hResidualLocalYDT", "hResidualLocalYDT", 200, -10, 10);
    hResidualLocalXCSC = fs->make<TH1F>("hResidualLocalXCSC", "hResidualLocalXCSC", 200, -10, 10);
    hResidualLocalPhiCSC = fs->make<TH1F>("hResidualLocalPhiCSC", "hResidualLocalPhiCSC", 100, -1, 1);
    hResidualLocalThetaCSC = fs->make<TH1F>("hResidualLocalThetaCSC", "hResidualLocalThetaCSC", 100, -1, 1);
    hResidualLocalYCSC = fs->make<TH1F>("hResidualLocalYCSC", "hResidualLocalYCSC", 200, -10, 10);
    hResidualGlobalRPhiDT = fs->make<TH1F>("hResidualGlobalRPhiDT", "hResidualGlobalRPhiDT", 200, -10, 10);
    hResidualGlobalPhiDT = fs->make<TH1F>("hResidualGlobalPhiDT", "hResidualGlobalPhiDT", 100, -1, 1);
    hResidualGlobalThetaDT = fs->make<TH1F>("hResidualGlobalThetaDT", "hResidualGlobalThetaDT", 100, -1, 1);
    hResidualGlobalZDT = fs->make<TH1F>("hResidualGlobalZDT", "hResidualGlobalZDT", 200, -10, 10);
    hResidualGlobalRPhiCSC = fs->make<TH1F>("hResidualGlobalRPhiCSC", "hResidualGlobalRPhiCSC", 200, -10, 10);
    hResidualGlobalPhiCSC = fs->make<TH1F>("hResidualGlobalPhiCSC", "hResidualGlobalPhiCSC", 100, -1, 1);
    hResidualGlobalThetaCSC = fs->make<TH1F>("hResidualGlobalThetaCSC", "hResidualGlobalThetaCSC", 100, -1, 1);
    hResidualGlobalRCSC = fs->make<TH1F>("hResidualGlobalRCSC", "hResidualGlobalRCSC", 200, -10, 10);
 
    // DT Wheels
    hResidualLocalXDT_W[0] = fs->make<TH1F>("hResidualLocalXDT_W-2", "hResidualLocalXDT_W-2", 200, -10, 10);
    hResidualLocalPhiDT_W[0] = fs->make<TH1F>("hResidualLocalPhiDT_W-2", "hResidualLocalPhiDT_W-2", 200, -1, 1);
    hResidualLocalThetaDT_W[0] = fs->make<TH1F>("hResidualLocalThetaDT_W-2", "hResidualLocalThetaDT_W-2", 200, -1, 1);
    hResidualLocalYDT_W[0] = fs->make<TH1F>("hResidualLocalYDT_W-2", "hResidualLocalYDT_W-2", 200, -10, 10);
    hResidualLocalXDT_W[1] = fs->make<TH1F>("hResidualLocalXDT_W-1", "hResidualLocalXDT_W-1", 200, -10, 10);
    hResidualLocalPhiDT_W[1] = fs->make<TH1F>("hResidualLocalPhiDT_W-1", "hResidualLocalPhiDT_W-1", 200, -1, 1);
    hResidualLocalThetaDT_W[1] = fs->make<TH1F>("hResidualLocalThetaDT_W-1", "hResidualLocalThetaDT_W-1", 200, -1, 1);
    hResidualLocalYDT_W[1] = fs->make<TH1F>("hResidualLocalYDT_W-1", "hResidualLocalYDT_W-1", 200, -10, 10);
    hResidualLocalXDT_W[2] = fs->make<TH1F>("hResidualLocalXDT_W0", "hResidualLocalXDT_W0", 200, -10, 10);
    hResidualLocalPhiDT_W[2] = fs->make<TH1F>("hResidualLocalPhiDT_W0", "hResidualLocalPhiDT_W0", 200, -1, 1);
    hResidualLocalThetaDT_W[2] = fs->make<TH1F>("hResidualLocalThetaDT_W0", "hResidualLocalThetaDT_W0", 200, -1, 1);
    hResidualLocalYDT_W[2] = fs->make<TH1F>("hResidualLocalYDT_W0", "hResidualLocalYDT_W0", 200, -10, 10);
    hResidualLocalXDT_W[3] = fs->make<TH1F>("hResidualLocalXDT_W1", "hResidualLocalXDT_W1", 200, -10, 10);
    hResidualLocalPhiDT_W[3] = fs->make<TH1F>("hResidualLocalPhiDT_W1", "hResidualLocalPhiDT_W1", 200, -1, 1);
    hResidualLocalThetaDT_W[3] = fs->make<TH1F>("hResidualLocalThetaDT_W1", "hResidualLocalThetaDT_W1", 200, -1, 1);
    hResidualLocalYDT_W[3] = fs->make<TH1F>("hResidualLocalYDT_W1", "hResidualLocalYDT_W1", 200, -10, 10);
    hResidualLocalXDT_W[4] = fs->make<TH1F>("hResidualLocalXDT_W2", "hResidualLocalXDT_W2", 200, -10, 10);
    hResidualLocalPhiDT_W[4] = fs->make<TH1F>("hResidualLocalPhiDT_W2", "hResidualLocalPhiDT_W2", 200, -1, 1);
    hResidualLocalThetaDT_W[4] = fs->make<TH1F>("hResidualLocalThetaDT_W2", "hResidualLocalThetaDT_W2", 200, -1, 1);
    hResidualLocalYDT_W[4] = fs->make<TH1F>("hResidualLocalYDT_W2", "hResidualLocalYDT_W2", 200, -10, 10);
    hResidualGlobalRPhiDT_W[0] = fs->make<TH1F>("hResidualGlobalRPhiDT_W-2", "hResidualGlobalRPhiDT_W-2", 200, -10, 10);
    hResidualGlobalPhiDT_W[0] = fs->make<TH1F>("hResidualGlobalPhiDT_W-2", "hResidualGlobalPhiDT_W-2", 200, -1, 1);
    hResidualGlobalThetaDT_W[0] =
        fs->make<TH1F>("hResidualGlobalThetaDT_W-2", "hResidualGlobalThetaDT_W-2", 200, -1, 1);
    hResidualGlobalZDT_W[0] = fs->make<TH1F>("hResidualGlobalZDT_W-2", "hResidualGlobalZDT_W-2", 200, -10, 10);
    hResidualGlobalRPhiDT_W[1] = fs->make<TH1F>("hResidualGlobalRPhiDT_W-1", "hResidualGlobalRPhiDT_W-1", 200, -10, 10);
    hResidualGlobalPhiDT_W[1] = fs->make<TH1F>("hResidualGlobalPhiDT_W-1", "hResidualGlobalPhiDT_W-1", 200, -1, 1);
    hResidualGlobalThetaDT_W[1] =
        fs->make<TH1F>("hResidualGlobalThetaDT_W-1", "hResidualGlobalThetaDT_W-1", 200, -1, 1);
    hResidualGlobalZDT_W[1] = fs->make<TH1F>("hResidualGlobalZDT_W-1", "hResidualGlobalZDT_W-1", 200, -10, 10);
    hResidualGlobalRPhiDT_W[2] = fs->make<TH1F>("hResidualGlobalRPhiDT_W0", "hResidualGlobalRPhiDT_W0", 200, -10, 10);
    hResidualGlobalPhiDT_W[2] = fs->make<TH1F>("hResidualGlobalPhiDT_W0", "hResidualGlobalPhiDT_W0", 200, -1, 1);
    hResidualGlobalThetaDT_W[2] = fs->make<TH1F>("hResidualGlobalThetaDT_W0", "hResidualGlobalThetaDT_W0", 200, -1, 1);
    hResidualGlobalZDT_W[2] = fs->make<TH1F>("hResidualGlobalZDT_W0", "hResidualGlobalZDT_W0", 200, -10, 10);
    hResidualGlobalRPhiDT_W[3] = fs->make<TH1F>("hResidualGlobalRPhiDT_W1", "hResidualGlobalRPhiDT_W1", 200, -10, 10);
    hResidualGlobalPhiDT_W[3] = fs->make<TH1F>("hResidualGlobalPhiDT_W1", "hResidualGlobalPhiDT_W1", 200, -1, 1);
    hResidualGlobalThetaDT_W[3] = fs->make<TH1F>("hResidualGlobalThetaDT_W1", "hResidualGlobalThetaDT_W1", 200, -1, 1);
    hResidualGlobalZDT_W[3] = fs->make<TH1F>("hResidualGlobalZDT_W1", "hResidualGlobalZDT_W1", 200, -10, 10);
    hResidualGlobalRPhiDT_W[4] = fs->make<TH1F>("hResidualGlobalRPhiDT_W2", "hResidualGlobalRPhiDT_W2", 200, -10, 10);
    hResidualGlobalPhiDT_W[4] = fs->make<TH1F>("hResidualGlobalPhiDT_W2", "hResidualGlobalPhiDT_W2", 200, -1, 1);
    hResidualGlobalThetaDT_W[4] = fs->make<TH1F>("hResidualGlobalThetaDT_W2", "hResidualGlobalThetaDT_W2", 200, -1, 1);
    hResidualGlobalZDT_W[4] = fs->make<TH1F>("hResidualGlobalZDT_W2", "hResidualGlobalZDT_W2", 200, -10, 10);
 
    // DT Stations
    hResidualLocalXDT_MB[0] = fs->make<TH1F>("hResidualLocalXDT_MB-2/1", "hResidualLocalXDT_MB-2/1", 200, -10, 10);
    hResidualLocalPhiDT_MB[0] = fs->make<TH1F>("hResidualLocalPhiDT_MB-2/1", "hResidualLocalPhiDT_MB-2/1", 200, -1, 1);
    hResidualLocalThetaDT_MB[0] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-2/1", "hResidualLocalThetaDT_MB-2/1", 200, -1, 1);
    hResidualLocalYDT_MB[0] = fs->make<TH1F>("hResidualLocalYDT_MB-2/1", "hResidualLocalYDT_MB-2/1", 200, -10, 10);
    hResidualLocalXDT_MB[1] = fs->make<TH1F>("hResidualLocalXDT_MB-2/2", "hResidualLocalXDT_MB-2/2", 200, -10, 10);
    hResidualLocalPhiDT_MB[1] = fs->make<TH1F>("hResidualLocalPhiDT_MB-2/2", "hResidualLocalPhiDT_MB-2/2", 200, -1, 1);
    hResidualLocalThetaDT_MB[1] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-2/2", "hResidualLocalThetaDT_MB-2/2", 200, -1, 1);
    hResidualLocalYDT_MB[1] = fs->make<TH1F>("hResidualLocalYDT_MB-2/2", "hResidualLocalYDT_MB-2/2", 200, -10, 10);
    hResidualLocalXDT_MB[2] = fs->make<TH1F>("hResidualLocalXDT_MB-2/3", "hResidualLocalXDT_MB-2/3", 200, -10, 10);
    hResidualLocalPhiDT_MB[2] = fs->make<TH1F>("hResidualLocalPhiDT_MB-2/3", "hResidualLocalPhiDT_MB-2/3", 200, -1, 1);
    hResidualLocalThetaDT_MB[2] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-2/3", "hResidualLocalThetaDT_MB-2/3", 200, -1, 1);
    hResidualLocalYDT_MB[2] = fs->make<TH1F>("hResidualLocalYDT_MB-2/3", "hResidualLocalYDT_MB-2/3", 200, -10, 10);
    hResidualLocalXDT_MB[3] = fs->make<TH1F>("hResidualLocalXDT_MB-2/4", "hResidualLocalXDT_MB-2/4", 200, -10, 10);
    hResidualLocalPhiDT_MB[3] = fs->make<TH1F>("hResidualLocalPhiDT_MB-2/4", "hResidualLocalPhiDT_MB-2/4", 200, -1, 1);
    hResidualLocalThetaDT_MB[3] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-2/4", "hResidualLocalThetaDT_MB-2/4", 200, -1, 1);
    hResidualLocalYDT_MB[3] = fs->make<TH1F>("hResidualLocalYDT_MB-2/4", "hResidualLocalYDT_MB-2/4", 200, -10, 10);
    hResidualLocalXDT_MB[4] = fs->make<TH1F>("hResidualLocalXDT_MB-1/1", "hResidualLocalXDT_MB-1/1", 200, -10, 10);
    hResidualLocalPhiDT_MB[4] = fs->make<TH1F>("hResidualLocalPhiDT_MB-1/1", "hResidualLocalPhiDT_MB-1/1", 200, -1, 1);
    hResidualLocalThetaDT_MB[4] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-1/1", "hResidualLocalThetaDT_MB-1/1", 200, -1, 1);
    hResidualLocalYDT_MB[4] = fs->make<TH1F>("hResidualLocalYDT_MB-1/1", "hResidualLocalYDT_MB-1/1", 200, -10, 10);
    hResidualLocalXDT_MB[5] = fs->make<TH1F>("hResidualLocalXDT_MB-1/2", "hResidualLocalXDT_MB-1/2", 200, -10, 10);
    hResidualLocalPhiDT_MB[5] = fs->make<TH1F>("hResidualLocalPhiDT_MB-1/2", "hResidualLocalPhiDT_MB-1/2", 200, -1, 1);
    hResidualLocalThetaDT_MB[5] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-1/2", "hResidualLocalThetaDT_MB-1/2", 200, -1, 1);
    hResidualLocalYDT_MB[5] = fs->make<TH1F>("hResidualLocalYDT_MB-1/2", "hResidualLocalYDT_MB-1/2", 200, -10, 10);
    hResidualLocalXDT_MB[6] = fs->make<TH1F>("hResidualLocalXDT_MB-1/3", "hResidualLocalXDT_MB-1/3", 200, -10, 10);
    hResidualLocalPhiDT_MB[6] = fs->make<TH1F>("hResidualLocalPhiDT_MB-1/3", "hResidualLocalPhiDT_MB-1/3", 200, -1, 1);
    hResidualLocalThetaDT_MB[6] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-1/3", "hResidualLocalThetaDT_MB-1/3", 200, -1, 1);
    hResidualLocalYDT_MB[6] = fs->make<TH1F>("hResidualLocalYDT_MB-1/3", "hResidualLocalYDT_MB-1/3", 200, -10, 10);
    hResidualLocalXDT_MB[7] = fs->make<TH1F>("hResidualLocalXDT_MB-1/4", "hResidualLocalXDT_MB-1/4", 200, -10, 10);
    hResidualLocalPhiDT_MB[7] = fs->make<TH1F>("hResidualLocalPhiDT_MB-1/4", "hResidualLocalPhiDT_MB-1/4", 200, -1, 1);
    hResidualLocalThetaDT_MB[7] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB-1/4", "hResidualLocalThetaDT_MB-1/4", 200, -1, 1);
    hResidualLocalYDT_MB[7] = fs->make<TH1F>("hResidualLocalYDT_MB-1/4", "hResidualLocalYDT_MB-1/4", 200, -10, 10);
    hResidualLocalXDT_MB[8] = fs->make<TH1F>("hResidualLocalXDT_MB0/1", "hResidualLocalXDT_MB0/1", 200, -10, 10);
    hResidualLocalPhiDT_MB[8] = fs->make<TH1F>("hResidualLocalPhiDT_MB0/1", "hResidualLocalPhiDT_MB0/1", 200, -1, 1);
    hResidualLocalThetaDT_MB[8] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB0/1", "hResidualLocalThetaDT_MB0/1", 200, -1, 1);
    hResidualLocalYDT_MB[8] = fs->make<TH1F>("hResidualLocalYDT_MB0/1", "hResidualLocalYDT_MB0/1", 200, -10, 10);
    hResidualLocalXDT_MB[9] = fs->make<TH1F>("hResidualLocalXDT_MB0/2", "hResidualLocalXDT_MB0/2", 200, -10, 10);
    hResidualLocalPhiDT_MB[9] = fs->make<TH1F>("hResidualLocalPhiDT_MB0/2", "hResidualLocalPhiDT_MB0/2", 200, -1, 1);
    hResidualLocalThetaDT_MB[9] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB0/2", "hResidualLocalThetaDT_MB0/2", 200, -1, 1);
    hResidualLocalYDT_MB[9] = fs->make<TH1F>("hResidualLocalYDT_MB0/2", "hResidualLocalYDT_MB0/2", 200, -10, 10);
    hResidualLocalXDT_MB[10] = fs->make<TH1F>("hResidualLocalXDT_MB0/3", "hResidualLocalXDT_MB0/3", 200, -10, 10);
    hResidualLocalThetaDT_MB[10] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB0/3", "hResidualLocalThetaDT_MB0/3", 200, -1, 1);
    hResidualLocalPhiDT_MB[10] = fs->make<TH1F>("hResidualLocalPhiDT_MB0/3", "hResidualLocalPhiDT_MB0/3", 200, -1, 1);
    hResidualLocalYDT_MB[10] = fs->make<TH1F>("hResidualLocalYDT_MB0/3", "hResidualLocalYDT_MB0/3", 200, -10, 10);
    hResidualLocalXDT_MB[11] = fs->make<TH1F>("hResidualLocalXDT_MB0/4", "hResidualLocalXDT_MB0/4", 200, -10, 10);
    hResidualLocalPhiDT_MB[11] = fs->make<TH1F>("hResidualLocalPhiDT_MB0/4", "hResidualLocalPhiDT_MB0/4", 200, -1, 1);
    hResidualLocalThetaDT_MB[11] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB0/4", "hResidualLocalThetaDT_MB0/4", 200, -1, 1);
    hResidualLocalYDT_MB[11] = fs->make<TH1F>("hResidualLocalYDT_MB0/4", "hResidualLocalYDT_MB0/4", 200, -10, 10);
    hResidualLocalXDT_MB[12] = fs->make<TH1F>("hResidualLocalXDT_MB1/1", "hResidualLocalXDT_MB1/1", 200, -10, 10);
    hResidualLocalPhiDT_MB[12] = fs->make<TH1F>("hResidualLocalPhiDT_MB1/1", "hResidualLocalPhiDT_MB1/1", 200, -1, 1);
    hResidualLocalThetaDT_MB[12] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB1/1", "hResidualLocalThetaDT_MB1/1", 200, -1, 1);
    hResidualLocalYDT_MB[12] = fs->make<TH1F>("hResidualLocalYDT_MB1/1", "hResidualLocalYDT_MB1/1", 200, -10, 10);
    hResidualLocalXDT_MB[13] = fs->make<TH1F>("hResidualLocalXDT_MB1/2", "hResidualLocalXDT_MB1/2", 200, -10, 10);
    hResidualLocalPhiDT_MB[13] = fs->make<TH1F>("hResidualLocalPhiDT_MB1/2", "hResidualLocalPhiDT_MB1/2", 200, -1, 1);
    hResidualLocalThetaDT_MB[13] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB1/2", "hResidualLocalThetaDT_MB1/2", 200, -1, 1);
    hResidualLocalYDT_MB[13] = fs->make<TH1F>("hResidualLocalYDT_MB1/2", "hResidualLocalYDT_MB1/2", 200, -10, 10);
    hResidualLocalXDT_MB[14] = fs->make<TH1F>("hResidualLocalXDT_MB1/3", "hResidualLocalXDT_MB1/3", 200, -10, 10);
    hResidualLocalPhiDT_MB[14] = fs->make<TH1F>("hResidualLocalPhiDT_MB1/3", "hResidualLocalPhiDT_MB1/3", 200, -1, 1);
    hResidualLocalThetaDT_MB[14] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB1/3", "hResidualLocalThetaDT_MB1/3", 200, -1, 1);
    hResidualLocalYDT_MB[14] = fs->make<TH1F>("hResidualLocalYDT_MB1/3", "hResidualLocalYDT_MB1/3", 200, -10, 10);
    hResidualLocalXDT_MB[15] = fs->make<TH1F>("hResidualLocalXDT_MB1/4", "hResidualLocalXDT_MB1/4", 200, -10, 10);
    hResidualLocalPhiDT_MB[15] = fs->make<TH1F>("hResidualLocalPhiDT_MB1/4", "hResidualLocalPhiDT_MB1/4", 200, -1, 1);
    hResidualLocalThetaDT_MB[15] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB1/4", "hResidualLocalThetaDT_MB1/4", 200, -1, 1);
    hResidualLocalYDT_MB[15] = fs->make<TH1F>("hResidualLocalYDT_MB1/4", "hResidualLocalYDT_MB1/4", 200, -10, 10);
    hResidualLocalXDT_MB[16] = fs->make<TH1F>("hResidualLocalXDT_MB2/1", "hResidualLocalXDT_MB2/1", 200, -10, 10);
    hResidualLocalPhiDT_MB[16] = fs->make<TH1F>("hResidualLocalPhiDT_MB2/1", "hResidualLocalPhiDT_MB2/1", 200, -1, 1);
    hResidualLocalThetaDT_MB[16] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB2/1", "hResidualLocalThetaDT_MB2/1", 200, -1, 1);
    hResidualLocalYDT_MB[16] = fs->make<TH1F>("hResidualLocalYDT_MB2/1", "hResidualLocalYDT_MB2/1", 200, -10, 10);
    hResidualLocalXDT_MB[17] = fs->make<TH1F>("hResidualLocalXDT_MB2/2", "hResidualLocalXDT_MB2/2", 200, -10, 10);
    hResidualLocalPhiDT_MB[17] = fs->make<TH1F>("hResidualLocalPhiDT_MB2/2", "hResidualLocalPhiDT_MB2/2", 200, -1, 1);
    hResidualLocalThetaDT_MB[17] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB2/2", "hResidualLocalThetaDT_MB2/2", 200, -1, 1);
    hResidualLocalYDT_MB[17] = fs->make<TH1F>("hResidualLocalYDT_MB2/2", "hResidualLocalYDT_MB2/2", 200, -10, 10);
    hResidualLocalXDT_MB[18] = fs->make<TH1F>("hResidualLocalXDT_MB2/3", "hResidualLocalXDT_MB2/3", 200, -10, 10);
    hResidualLocalPhiDT_MB[18] = fs->make<TH1F>("hResidualLocalPhiDT_MB2/3", "hResidualLocalPhiDT_MB2/3", 200, -1, 1);
    hResidualLocalThetaDT_MB[18] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB2/3", "hResidualLocalThetaDT_MB2/3", 200, -1, 1);
    hResidualLocalYDT_MB[18] = fs->make<TH1F>("hResidualLocalYDT_MB2/3", "hResidualLocalYDT_MB2/3", 200, -10, 10);
    hResidualLocalXDT_MB[19] = fs->make<TH1F>("hResidualLocalXDT_MB2/4", "hResidualLocalXDT_MB2/4", 200, -10, 10);
    hResidualLocalPhiDT_MB[19] = fs->make<TH1F>("hResidualLocalPhiDT_MB2/4", "hResidualLocalPhiDT_MB2/4", 200, -1, 1);
    hResidualLocalThetaDT_MB[19] =
        fs->make<TH1F>("hResidualLocalThetaDT_MB2/4", "hResidualLocalThetaDT_MB2/4", 200, -1, 1);
    hResidualLocalYDT_MB[19] = fs->make<TH1F>("hResidualLocalYDT_MB2/4", "hResidualLocalYDT_MB2/4", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[0] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-2/1", "hResidualGlobalRPhiDT_MB-2/1", 200, -10, 10);
    hResidualGlobalPhiDT_MB[0] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-2/1", "hResidualGlobalPhiDT_MB-2/1", 200, -1, 1);
    hResidualGlobalThetaDT_MB[0] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-2/1", "hResidualGlobalThetaDT_MB-2/1", 200, -1, 1);
    hResidualGlobalZDT_MB[0] = fs->make<TH1F>("hResidualGlobalZDT_MB-2/1", "hResidualGlobalZDT_MB-2/1", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[1] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-2/2", "hResidualGlobalRPhiDT_MB-2/2", 200, -10, 10);
    hResidualGlobalPhiDT_MB[1] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-2/2", "hResidualGlobalPhiDT_MB-2/2", 200, -1, 1);
    hResidualGlobalThetaDT_MB[1] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-2/2", "hResidualGlobalThetaDT_MB-2/2", 200, -1, 1);
    hResidualGlobalZDT_MB[1] = fs->make<TH1F>("hResidualGlobalZDT_MB-2/2", "hResidualGlobalZDT_MB-2/2", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[2] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-2/3", "hResidualGlobalRPhiDT_MB-2/3", 200, -10, 10);
    hResidualGlobalPhiDT_MB[2] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-2/3", "hResidualGlobalPhiDT_MB-2/3", 200, -1, 1);
    hResidualGlobalThetaDT_MB[2] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-2/3", "hResidualGlobalThetaDT_MB-2/3", 200, -1, 1);
    hResidualGlobalZDT_MB[2] = fs->make<TH1F>("hResidualGlobalZDT_MB-2/3", "hResidualGlobalZDT_MB-2/3", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[3] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-2/4", "hResidualGlobalRPhiDT_MB-2/4", 200, -10, 10);
    hResidualGlobalPhiDT_MB[3] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-2/4", "hResidualGlobalPhiDT_MB-2/4", 200, -1, 1);
    hResidualGlobalThetaDT_MB[3] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-2/4", "hResidualGlobalThetaDT_MB-2/4", 200, -1, 1);
    hResidualGlobalZDT_MB[3] = fs->make<TH1F>("hResidualGlobalZDT_MB-2/4", "hResidualGlobalZDT_MB-2/4", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[4] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-1/1", "hResidualGlobalRPhiDT_MB-1/1", 200, -10, 10);
    hResidualGlobalPhiDT_MB[4] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-1/1", "hResidualGlobalPhiDT_MB-1/1", 200, -1, 1);
    hResidualGlobalThetaDT_MB[4] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-1/1", "hResidualGlobalThetaDT_MB-1/1", 200, -1, 1);
    hResidualGlobalZDT_MB[4] = fs->make<TH1F>("hResidualGlobalZDT_MB-1/1", "hResidualGlobalZDT_MB-1/1", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[5] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-1/2", "hResidualGlobalRPhiDT_MB-1/2", 200, -10, 10);
    hResidualGlobalPhiDT_MB[5] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-1/2", "hResidualGlobalPhiDT_MB-1/2", 200, -1, 1);
    hResidualGlobalThetaDT_MB[5] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-1/2", "hResidualGlobalThetaDT_MB-1/2", 200, -1, 1);
    hResidualGlobalZDT_MB[5] = fs->make<TH1F>("hResidualGlobalZDT_MB-1/2", "hResidualGlobalZDT_MB-1/2", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[6] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-1/3", "hResidualGlobalRPhiDT_MB-1/3", 200, -10, 10);
    hResidualGlobalPhiDT_MB[6] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-1/3", "hResidualGlobalPhiDT_MB-1/3", 200, -1, 1);
    hResidualGlobalThetaDT_MB[6] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-1/3", "hResidualGlobalThetaDT_MB-1/3", 200, -1, 1);
    hResidualGlobalZDT_MB[6] = fs->make<TH1F>("hResidualGlobalZDT_MB-1/3", "hResidualGlobalZDT_MB-1/3", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[7] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB-1/4", "hResidualGlobalRPhiDT_MB-1/4", 200, -10, 10);
    hResidualGlobalPhiDT_MB[7] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB-1/4", "hResidualGlobalPhiDT_MB-1/4", 200, -1, 1);
    hResidualGlobalThetaDT_MB[7] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB-1/4", "hResidualGlobalThetaDT_MB-1/4", 200, -1, 1);
    hResidualGlobalZDT_MB[7] = fs->make<TH1F>("hResidualGlobalZDT_MB-1/4", "hResidualGlobalZDT_MB-1/4", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[8] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB0/1", "hResidualGlobalRPhiDT_MB0/1", 200, -10, 10);
    hResidualGlobalPhiDT_MB[8] = fs->make<TH1F>("hResidualGlobalPhiDT_MB0/1", "hResidualGlobalPhiDT_MB0/1", 200, -1, 1);
    hResidualGlobalThetaDT_MB[8] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB0/1", "hResidualGlobalThetaDT_MB0/1", 200, -1, 1);
    hResidualGlobalZDT_MB[8] = fs->make<TH1F>("hResidualGlobalZDT_MB0/1", "hResidualGlobalZDT_MB0/1", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[9] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB0/2", "hResidualGlobalRPhiDT_MB0/2", 200, -10, 10);
    hResidualGlobalPhiDT_MB[9] = fs->make<TH1F>("hResidualGlobalPhiDT_MB0/2", "hResidualGlobalPhiDT_MB0/2", 200, -1, 1);
    hResidualGlobalThetaDT_MB[9] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB0/2", "hResidualGlobalThetaDT_MB0/2", 200, -1, 1);
    hResidualGlobalZDT_MB[9] = fs->make<TH1F>("hResidualGlobalZDT_MB0/2", "hResidualGlobalZDT_MB0/2", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[10] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB0/3", "hResidualGlobalRPhiDT_MB0/3", 200, -10, 10);
    hResidualGlobalThetaDT_MB[10] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB0/3", "hResidualGlobalThetaDT_MB0/3", 200, -1, 1);
    hResidualGlobalPhiDT_MB[10] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB0/3", "hResidualGlobalPhiDT_MB0/3", 200, -1, 1);
    hResidualGlobalZDT_MB[10] = fs->make<TH1F>("hResidualGlobalZDT_MB0/3", "hResidualGlobalZDT_MB0/3", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[11] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB0/4", "hResidualGlobalRPhiDT_MB0/4", 200, -10, 10);
    hResidualGlobalPhiDT_MB[11] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB0/4", "hResidualGlobalPhiDT_MB0/4", 200, -1, 1);
    hResidualGlobalThetaDT_MB[11] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB0/4", "hResidualGlobalThetaDT_MB0/4", 200, -1, 1);
    hResidualGlobalZDT_MB[11] = fs->make<TH1F>("hResidualGlobalZDT_MB0/4", "hResidualGlobalZDT_MB0/4", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[12] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB1/1", "hResidualGlobalRPhiDT_MB1/1", 200, -10, 10);
    hResidualGlobalPhiDT_MB[12] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB1/1", "hResidualGlobalPhiDT_MB1/1", 200, -1, 1);
    hResidualGlobalThetaDT_MB[12] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB1/1", "hResidualGlobalThetaDT_MB1/1", 200, -1, 1);
    hResidualGlobalZDT_MB[12] = fs->make<TH1F>("hResidualGlobalZDT_MB1/1", "hResidualGlobalZDT_MB1/1", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[13] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB1/2", "hResidualGlobalRPhiDT_MB1/2", 200, -10, 10);
    hResidualGlobalPhiDT_MB[13] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB1/2", "hResidualGlobalPhiDT_MB1/2", 200, -1, 1);
    hResidualGlobalThetaDT_MB[13] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB1/2", "hResidualGlobalThetaDT_MB1/2", 200, -1, 1);
    hResidualGlobalZDT_MB[13] = fs->make<TH1F>("hResidualGlobalZDT_MB1/2", "hResidualGlobalZDT_MB1/2", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[14] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB1/3", "hResidualGlobalRPhiDT_MB1/3", 200, -10, 10);
    hResidualGlobalPhiDT_MB[14] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB1/3", "hResidualGlobalPhiDT_MB1/3", 200, -1, 1);
    hResidualGlobalThetaDT_MB[14] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB1/3", "hResidualGlobalThetaDT_MB1/3", 200, -1, 1);
    hResidualGlobalZDT_MB[14] = fs->make<TH1F>("hResidualGlobalZDT_MB1/3", "hResidualGlobalZDT_MB1/3", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[15] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB1/4", "hResidualGlobalRPhiDT_MB1/4", 200, -10, 10);
    hResidualGlobalPhiDT_MB[15] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB1/4", "hResidualGlobalPhiDT_MB1/4", 200, -1, 1);
    hResidualGlobalThetaDT_MB[15] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB1/4", "hResidualGlobalThetaDT_MB1/4", 200, -1, 1);
    hResidualGlobalZDT_MB[15] = fs->make<TH1F>("hResidualGlobalZDT_MB1/4", "hResidualGlobalZDT_MB1/4", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[16] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB2/1", "hResidualGlobalRPhiDT_MB2/1", 200, -10, 10);
    hResidualGlobalPhiDT_MB[16] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB2/1", "hResidualGlobalPhiDT_MB2/1", 200, -1, 1);
    hResidualGlobalThetaDT_MB[16] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB2/1", "hResidualGlobalThetaDT_MB2/1", 200, -1, 1);
    hResidualGlobalZDT_MB[16] = fs->make<TH1F>("hResidualGlobalZDT_MB2/1", "hResidualGlobalZDT_MB2/1", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[17] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB2/2", "hResidualGlobalRPhiDT_MB2/2", 200, -10, 10);
    hResidualGlobalPhiDT_MB[17] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB2/2", "hResidualGlobalPhiDT_MB2/2", 200, -1, 1);
    hResidualGlobalThetaDT_MB[17] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB2/2", "hResidualGlobalThetaDT_MB2/2", 200, -1, 1);
    hResidualGlobalZDT_MB[17] = fs->make<TH1F>("hResidualGlobalZDT_MB2/2", "hResidualGlobalZDT_MB2/2", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[18] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB2/3", "hResidualGlobalRPhiDT_MB2/3", 200, -10, 10);
    hResidualGlobalPhiDT_MB[18] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB2/3", "hResidualGlobalPhiDT_MB2/3", 200, -1, 1);
    hResidualGlobalThetaDT_MB[18] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB2/3", "hResidualGlobalThetaDT_MB2/3", 200, -1, 1);
    hResidualGlobalZDT_MB[18] = fs->make<TH1F>("hResidualGlobalZDT_MB2/3", "hResidualGlobalZDT_MB2/3", 200, -10, 10);
    hResidualGlobalRPhiDT_MB[19] =
        fs->make<TH1F>("hResidualGlobalRPhiDT_MB2/4", "hResidualGlobalRPhiDT_MB2/4", 200, -10, 10);
    hResidualGlobalPhiDT_MB[19] =
        fs->make<TH1F>("hResidualGlobalPhiDT_MB2/4", "hResidualGlobalPhiDT_MB2/4", 200, -1, 1);
    hResidualGlobalThetaDT_MB[19] =
        fs->make<TH1F>("hResidualGlobalThetaDT_MB2/4", "hResidualGlobalThetaDT_MB2/4", 200, -1, 1);
    hResidualGlobalZDT_MB[19] = fs->make<TH1F>("hResidualGlobalZDT_MB2/4", "hResidualGlobalZDT_MB2/4", 200, -10, 10);
 
    // CSC Stations
    hResidualLocalXCSC_ME[0] = fs->make<TH1F>("hResidualLocalXCSC_ME-4/1", "hResidualLocalXCSC_ME-4/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[0] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-4/1", "hResidualLocalPhiCSC_ME-4/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[0] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-4/1", "hResidualLocalThetaCSC_ME-4/1", 200, -1, 1);
    hResidualLocalYCSC_ME[0] = fs->make<TH1F>("hResidualLocalYCSC_ME-4/1", "hResidualLocalYCSC_ME-4/1", 200, -10, 10);
    hResidualLocalXCSC_ME[1] = fs->make<TH1F>("hResidualLocalXCSC_ME-4/2", "hResidualLocalXCSC_ME-4/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[1] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-4/2", "hResidualLocalPhiCSC_ME-4/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[1] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-4/2", "hResidualLocalThetaCSC_ME-4/2", 200, -1, 1);
    hResidualLocalYCSC_ME[1] = fs->make<TH1F>("hResidualLocalYCSC_ME-4/2", "hResidualLocalYCSC_ME-4/2", 200, -10, 10);
    hResidualLocalXCSC_ME[2] = fs->make<TH1F>("hResidualLocalXCSC_ME-3/1", "hResidualLocalXCSC_ME-3/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[2] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-3/1", "hResidualLocalPhiCSC_ME-3/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[2] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-3/1", "hResidualLocalThetaCSC_ME-3/1", 200, -1, 1);
    hResidualLocalYCSC_ME[2] = fs->make<TH1F>("hResidualLocalYCSC_ME-3/1", "hResidualLocalYCSC_ME-3/1", 200, -10, 10);
    hResidualLocalXCSC_ME[3] = fs->make<TH1F>("hResidualLocalXCSC_ME-3/2", "hResidualLocalXCSC_ME-3/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[3] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-3/2", "hResidualLocalPhiCSC_ME-3/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[3] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-3/2", "hResidualLocalThetaCSC_ME-3/2", 200, -1, 1);
    hResidualLocalYCSC_ME[3] = fs->make<TH1F>("hResidualLocalYCSC_ME-3/2", "hResidualLocalYCSC_ME-3/2", 200, -10, 10);
    hResidualLocalXCSC_ME[4] = fs->make<TH1F>("hResidualLocalXCSC_ME-2/1", "hResidualLocalXCSC_ME-2/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[4] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-2/1", "hResidualLocalPhiCSC_ME-2/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[4] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-2/1", "hResidualLocalThetaCSC_ME-2/1", 200, -1, 1);
    hResidualLocalYCSC_ME[4] = fs->make<TH1F>("hResidualLocalYCSC_ME-2/1", "hResidualLocalYCSC_ME-2/1", 200, -10, 10);
    hResidualLocalXCSC_ME[5] = fs->make<TH1F>("hResidualLocalXCSC_ME-2/2", "hResidualLocalXCSC_ME-2/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[5] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-2/2", "hResidualLocalPhiCSC_ME-2/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[5] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-2/2", "hResidualLocalThetaCSC_ME-2/2", 200, -1, 1);
    hResidualLocalYCSC_ME[5] = fs->make<TH1F>("hResidualLocalYCSC_ME-2/2", "hResidualLocalYCSC_ME-2/2", 200, -10, 10);
    hResidualLocalXCSC_ME[6] = fs->make<TH1F>("hResidualLocalXCSC_ME-1/1", "hResidualLocalXCSC_ME-1/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[6] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-1/1", "hResidualLocalPhiCSC_ME-1/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[6] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-1/1", "hResidualLocalThetaCSC_ME-1/1", 200, -1, 1);
    hResidualLocalYCSC_ME[6] = fs->make<TH1F>("hResidualLocalYCSC_ME-1/1", "hResidualLocalYCSC_ME-1/1", 200, -10, 10);
    hResidualLocalXCSC_ME[7] = fs->make<TH1F>("hResidualLocalXCSC_ME-1/2", "hResidualLocalXCSC_ME-1/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[7] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-1/2", "hResidualLocalPhiCSC_ME-1/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[7] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-1/2", "hResidualLocalThetaCSC_ME-1/2", 200, -1, 1);
    hResidualLocalYCSC_ME[7] = fs->make<TH1F>("hResidualLocalYCSC_ME-1/2", "hResidualLocalYCSC_ME-1/2", 200, -10, 10);
    hResidualLocalXCSC_ME[8] = fs->make<TH1F>("hResidualLocalXCSC_ME-1/3", "hResidualLocalXCSC_ME-1/3", 200, -10, 10);
    hResidualLocalPhiCSC_ME[8] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME-1/3", "hResidualLocalPhiCSC_ME-1/3", 200, -1, 1);
    hResidualLocalThetaCSC_ME[8] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME-1/3", "hResidualLocalThetaCSC_ME-1/3", 200, -1, 1);
    hResidualLocalYCSC_ME[8] = fs->make<TH1F>("hResidualLocalYCSC_ME-1/3", "hResidualLocalYCSC_ME-1/3", 200, -10, 10);
    hResidualLocalXCSC_ME[9] = fs->make<TH1F>("hResidualLocalXCSC_ME1/1", "hResidualLocalXCSC_ME1/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[9] = fs->make<TH1F>("hResidualLocalPhiCSC_ME1/1", "hResidualLocalPhiCSC_ME1/1", 100, -1, 1);
    hResidualLocalThetaCSC_ME[9] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME1/1", "hResidualLocalThetaCSC_ME1/1", 200, -1, 1);
    hResidualLocalYCSC_ME[9] = fs->make<TH1F>("hResidualLocalYCSC_ME1/1", "hResidualLocalYCSC_ME1/1", 200, -10, 10);
    hResidualLocalXCSC_ME[10] = fs->make<TH1F>("hResidualLocalXCSC_ME1/2", "hResidualLocalXCSC_ME1/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[10] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME1/2", "hResidualLocalPhiCSC_ME1/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[10] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME1/2", "hResidualLocalThetaCSC_ME1/2", 200, -1, 1);
    hResidualLocalYCSC_ME[10] = fs->make<TH1F>("hResidualLocalYCSC_ME1/2", "hResidualLocalYCSC_ME1/2", 200, -10, 10);
    hResidualLocalXCSC_ME[11] = fs->make<TH1F>("hResidualLocalXCSC_ME1/3", "hResidualLocalXCSC_ME1/3", 200, -10, 10);
    hResidualLocalPhiCSC_ME[11] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME1/3", "hResidualLocalPhiCSC_ME1/3", 200, -1, 1);
    hResidualLocalThetaCSC_ME[11] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME1/3", "hResidualLocalThetaCSC_ME1/3", 200, -1, 1);
    hResidualLocalYCSC_ME[11] = fs->make<TH1F>("hResidualLocalYCSC_ME1/3", "hResidualLocalYCSC_ME1/3", 200, -10, 10);
    hResidualLocalXCSC_ME[12] = fs->make<TH1F>("hResidualLocalXCSC_ME2/1", "hResidualLocalXCSC_ME2/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[12] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME2/1", "hResidualLocalPhiCSC_ME2/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[12] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME2/1", "hResidualLocalThetaCSC_ME2/1", 200, -1, 1);
    hResidualLocalYCSC_ME[12] = fs->make<TH1F>("hResidualLocalYCSC_ME2/1", "hResidualLocalYCSC_ME2/1", 200, -10, 10);
    hResidualLocalXCSC_ME[13] = fs->make<TH1F>("hResidualLocalXCSC_ME2/2", "hResidualLocalXCSC_ME2/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[13] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME2/2", "hResidualLocalPhiCSC_ME2/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[13] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME2/2", "hResidualLocalThetaCSC_ME2/2", 200, -1, 1);
    hResidualLocalYCSC_ME[13] = fs->make<TH1F>("hResidualLocalYCSC_ME2/2", "hResidualLocalYCSC_ME2/2", 200, -10, 10);
    hResidualLocalXCSC_ME[14] = fs->make<TH1F>("hResidualLocalXCSC_ME3/1", "hResidualLocalXCSC_ME3/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[14] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME3/1", "hResidualLocalPhiCSC_ME3/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[14] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME3/1", "hResidualLocalThetaCSC_ME3/1", 200, -1, 1);
    hResidualLocalYCSC_ME[14] = fs->make<TH1F>("hResidualLocalYCSC_ME3/1", "hResidualLocalYCSC_ME3/1", 200, -10, 10);
    hResidualLocalXCSC_ME[15] = fs->make<TH1F>("hResidualLocalXCSC_ME3/2", "hResidualLocalXCSC_ME3/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[15] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME3/2", "hResidualLocalPhiCSC_ME3/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[15] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME3/2", "hResidualLocalThetaCSC_ME3/2", 200, -1, 1);
    hResidualLocalYCSC_ME[15] = fs->make<TH1F>("hResidualLocalYCSC_ME3/2", "hResidualLocalYCSC_ME3/2", 200, -10, 10);
    hResidualLocalXCSC_ME[16] = fs->make<TH1F>("hResidualLocalXCSC_ME4/1", "hResidualLocalXCSC_ME4/1", 200, -10, 10);
    hResidualLocalPhiCSC_ME[16] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME4/1", "hResidualLocalPhiCSC_ME4/1", 200, -1, 1);
    hResidualLocalThetaCSC_ME[16] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME4/1", "hResidualLocalThetaCSC_ME4/1", 200, -1, 1);
    hResidualLocalYCSC_ME[16] = fs->make<TH1F>("hResidualLocalYCSC_ME4/1", "hResidualLocalYCSC_ME4/1", 200, -10, 10);
    hResidualLocalXCSC_ME[17] = fs->make<TH1F>("hResidualLocalXCSC_ME4/2", "hResidualLocalXCSC_ME4/2", 200, -10, 10);
    hResidualLocalPhiCSC_ME[17] =
        fs->make<TH1F>("hResidualLocalPhiCSC_ME4/2", "hResidualLocalPhiCSC_ME4/2", 200, -1, 1);
    hResidualLocalThetaCSC_ME[17] =
        fs->make<TH1F>("hResidualLocalThetaCSC_ME4/2", "hResidualLocalThetaCSC_ME4/2", 200, -1, 1);
    hResidualLocalYCSC_ME[17] = fs->make<TH1F>("hResidualLocalYCSC_ME4/2", "hResidualLocalYCSC_ME4/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[0] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-4/1", "hResidualGlobalRPhiCSC_ME-4/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[0] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-4/1", "hResidualGlobalPhiCSC_ME-4/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[0] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-4/1", "hResidualGlobalThetaCSC_ME-4/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[0] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-4/1", "hResidualGlobalRCSC_ME-4/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[1] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-4/2", "hResidualGlobalRPhiCSC_ME-4/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[1] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-4/2", "hResidualGlobalPhiCSC_ME-4/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[1] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-4/2", "hResidualGlobalThetaCSC_ME-4/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[1] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-4/2", "hResidualGlobalRCSC_ME-4/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[2] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-3/1", "hResidualGlobalRPhiCSC_ME-3/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[2] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-3/1", "hResidualGlobalPhiCSC_ME-3/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[2] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-3/1", "hResidualGlobalThetaCSC_ME-3/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[2] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-3/1", "hResidualGlobalRCSC_ME-3/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[3] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-3/2", "hResidualGlobalRPhiCSC_ME-3/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[3] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-3/2", "hResidualGlobalPhiCSC_ME-3/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[3] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-3/2", "hResidualGlobalThetaCSC_ME-3/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[3] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-3/2", "hResidualGlobalRCSC_ME-3/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[4] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-2/1", "hResidualGlobalRPhiCSC_ME-2/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[4] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-2/1", "hResidualGlobalPhiCSC_ME-2/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[4] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-2/1", "hResidualGlobalThetaCSC_ME-2/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[4] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-2/1", "hResidualGlobalRCSC_ME-2/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[5] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-2/2", "hResidualGlobalRPhiCSC_ME-2/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[5] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-2/2", "hResidualGlobalPhiCSC_ME-2/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[5] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-2/2", "hResidualGlobalThetaCSC_ME-2/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[5] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-2/2", "hResidualGlobalRCSC_ME-2/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[6] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-1/1", "hResidualGlobalRPhiCSC_ME-1/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[6] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-1/1", "hResidualGlobalPhiCSC_ME-1/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[6] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-1/1", "hResidualGlobalThetaCSC_ME-1/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[6] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-1/1", "hResidualGlobalRCSC_ME-1/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[7] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-1/2", "hResidualGlobalRPhiCSC_ME-1/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[7] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-1/2", "hResidualGlobalPhiCSC_ME-1/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[7] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-1/2", "hResidualGlobalThetaCSC_ME-1/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[7] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-1/2", "hResidualGlobalRCSC_ME-1/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[8] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME-1/3", "hResidualGlobalRPhiCSC_ME-1/3", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[8] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME-1/3", "hResidualGlobalPhiCSC_ME-1/3", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[8] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME-1/3", "hResidualGlobalThetaCSC_ME-1/3", 200, -1, 1);
    hResidualGlobalRCSC_ME[8] =
        fs->make<TH1F>("hResidualGlobalRCSC_ME-1/3", "hResidualGlobalRCSC_ME-1/3", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[9] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME1/1", "hResidualGlobalRPhiCSC_ME1/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[9] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME1/1", "hResidualGlobalPhiCSC_ME1/1", 100, -1, 1);
    hResidualGlobalThetaCSC_ME[9] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME1/1", "hResidualGlobalThetaCSC_ME1/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[9] = fs->make<TH1F>("hResidualGlobalRCSC_ME1/1", "hResidualGlobalRCSC_ME1/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[10] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME1/2", "hResidualGlobalRPhiCSC_ME1/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[10] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME1/2", "hResidualGlobalPhiCSC_ME1/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[10] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME1/2", "hResidualGlobalThetaCSC_ME1/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[10] = fs->make<TH1F>("hResidualGlobalRCSC_ME1/2", "hResidualGlobalRCSC_ME1/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[11] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME1/3", "hResidualGlobalRPhiCSC_ME1/3", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[11] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME1/3", "hResidualGlobalPhiCSC_ME1/3", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[11] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME1/3", "hResidualGlobalThetaCSC_ME1/3", 200, -1, 1);
    hResidualGlobalRCSC_ME[11] = fs->make<TH1F>("hResidualGlobalRCSC_ME1/3", "hResidualGlobalRCSC_ME1/3", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[12] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME2/1", "hResidualGlobalRPhiCSC_ME2/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[12] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME2/1", "hResidualGlobalPhiCSC_ME2/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[12] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME2/1", "hResidualGlobalThetaCSC_ME2/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[12] = fs->make<TH1F>("hResidualGlobalRCSC_ME2/1", "hResidualGlobalRCSC_ME2/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[13] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME2/2", "hResidualGlobalRPhiCSC_ME2/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[13] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME2/2", "hResidualGlobalPhiCSC_ME2/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[13] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME2/2", "hResidualGlobalThetaCSC_ME2/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[13] = fs->make<TH1F>("hResidualGlobalRCSC_ME2/2", "hResidualGlobalRCSC_ME2/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[14] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME3/1", "hResidualGlobalRPhiCSC_ME3/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[14] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME3/1", "hResidualGlobalPhiCSC_ME3/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[14] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME3/1", "hResidualGlobalThetaCSC_ME3/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[14] = fs->make<TH1F>("hResidualGlobalRCSC_ME3/1", "hResidualGlobalRCSC_ME3/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[15] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME3/2", "hResidualGlobalRPhiCSC_ME3/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[15] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME3/2", "hResidualGlobalPhiCSC_ME3/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[15] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME3/2", "hResidualGlobalThetaCSC_ME3/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[15] = fs->make<TH1F>("hResidualGlobalRCSC_ME3/2", "hResidualGlobalRCSC_ME3/2", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[16] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME4/1", "hResidualGlobalRPhiCSC_ME4/1", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[16] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME4/1", "hResidualGlobalPhiCSC_ME4/1", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[16] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME4/1", "hResidualGlobalThetaCSC_ME4/1", 200, -1, 1);
    hResidualGlobalRCSC_ME[16] = fs->make<TH1F>("hResidualGlobalRCSC_ME4/1", "hResidualGlobalRCSC_ME4/1", 200, -10, 10);
    hResidualGlobalRPhiCSC_ME[17] =
        fs->make<TH1F>("hResidualGlobalRPhiCSC_ME4/2", "hResidualGlobalRPhiCSC_ME4/2", 200, -10, 10);
    hResidualGlobalPhiCSC_ME[17] =
        fs->make<TH1F>("hResidualGlobalPhiCSC_ME4/2", "hResidualGlobalPhiCSC_ME4/2", 200, -1, 1);
    hResidualGlobalThetaCSC_ME[17] =
        fs->make<TH1F>("hResidualGlobalThetaCSC_ME4/2", "hResidualGlobalThetaCSC_ME4/2", 200, -1, 1);
    hResidualGlobalRCSC_ME[17] = fs->make<TH1F>("hResidualGlobalRCSC_ME4/2", "hResidualGlobalRCSC_ME4/2", 200, -10, 10);
 
    //DQM plots: mean residual with RMS as error
    hprofLocalXDT = fs->make<TH1F>("hprofLocalXDT", "Local X DT;;X (cm)", 280, 0, 280);
    hprofLocalPhiDT = fs->make<TH1F>("hprofLocalPhiDT", "Local Phi DT;;Phi (rad)", 280, 0, 280);
    hprofLocalThetaDT = fs->make<TH1F>("hprofLocalThetaDT", "Local Theta DT;;Theta (rad)", 280, 0, 280);
    hprofLocalYDT = fs->make<TH1F>("hprofLocalYDT", "Local Y DT;;Y (cm)", 280, 0, 280);
    hprofLocalXCSC = fs->make<TH1F>("hprofLocalXCSC", "Local X CSC;;X (cm)", 540, 0, 540);
    hprofLocalPhiCSC = fs->make<TH1F>("hprofLocalPhiCSC", "Local Phi CSC;;Phi (rad)", 540, 0, 540);
    hprofLocalThetaCSC = fs->make<TH1F>("hprofLocalThetaCSC", "Local Theta CSC;;Theta (rad)", 540, 0, 540);
    hprofLocalYCSC = fs->make<TH1F>("hprofLocalYCSC", "Local Y CSC;;Y (cm)", 540, 0, 540);
    hprofGlobalRPhiDT = fs->make<TH1F>("hprofGlobalRPhiDT", "Global RPhi DT;;RPhi (cm)", 280, 0, 280);
    hprofGlobalPhiDT = fs->make<TH1F>("hprofGlobalPhiDT", "Global Phi DT;;Phi (rad)", 280, 0, 280);
    hprofGlobalThetaDT = fs->make<TH1F>("hprofGlobalThetaDT", "Global Theta DT;;Theta (rad)", 280, 0, 280);
    hprofGlobalZDT = fs->make<TH1F>("hprofGlobalZDT", "Global Z DT;;Z (cm)", 280, 0, 280);
    hprofGlobalRPhiCSC = fs->make<TH1F>("hprofGlobalRPhiCSC", "Global RPhi CSC;;RPhi (cm)", 540, 0, 540);
    hprofGlobalPhiCSC = fs->make<TH1F>("hprofGlobalPhiCSC", "Global Phi CSC;;Phi (cm)", 540, 0, 540);
    hprofGlobalThetaCSC = fs->make<TH1F>("hprofGlobalThetaCSC", "Global Theta CSC;;Theta (rad)", 540, 0, 540);
    hprofGlobalRCSC = fs->make<TH1F>("hprofGlobalRCSC", "Global R CSC;;R (cm)", 540, 0, 540);
 
    // TH1F options
    hprofLocalXDT->GetXaxis()->SetLabelSize(0.025);
    hprofLocalPhiDT->GetXaxis()->SetLabelSize(0.025);
    hprofLocalThetaDT->GetXaxis()->SetLabelSize(0.025);
    hprofLocalYDT->GetXaxis()->SetLabelSize(0.025);
    hprofLocalXCSC->GetXaxis()->SetLabelSize(0.025);
    hprofLocalPhiCSC->GetXaxis()->SetLabelSize(0.025);
    hprofLocalThetaCSC->GetXaxis()->SetLabelSize(0.025);
    hprofLocalYCSC->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalRPhiDT->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalPhiDT->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalThetaDT->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalZDT->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalRPhiCSC->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalPhiCSC->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalThetaCSC->GetXaxis()->SetLabelSize(0.025);
    hprofGlobalRCSC->GetXaxis()->SetLabelSize(0.025);
 
    // TH2F histos definition
    hprofGlobalPositionDT = fs->make<TH2F>(
        "hprofGlobalPositionDT", "Global DT position (cm) absolute MEAN residuals;Sector;;cm", 14, 0, 14, 40, 0, 40);
    hprofGlobalAngleDT = fs->make<TH2F>(
        "hprofGlobalAngleDT", "Global DT angle (rad) absolute MEAN residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
    hprofGlobalPositionRmsDT = fs->make<TH2F>(
        "hprofGlobalPositionRmsDT", "Global DT position (cm) RMS residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
    hprofGlobalAngleRmsDT = fs->make<TH2F>(
        "hprofGlobalAngleRmsDT", "Global DT angle (rad) RMS residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
    hprofLocalPositionDT = fs->make<TH2F>(
        "hprofLocalPositionDT", "Local DT position (cm) absolute MEAN residuals;Sector;;cm", 14, 0, 14, 40, 0, 40);
    hprofLocalAngleDT = fs->make<TH2F>(
        "hprofLocalAngleDT", "Local DT angle (rad) absolute MEAN residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
    hprofLocalPositionRmsDT = fs->make<TH2F>(
        "hprofLocalPositionRmsDT", "Local DT position (cm) RMS residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
    hprofLocalAngleRmsDT =
        fs->make<TH2F>("hprofLocalAngleRmsDT", "Local DT angle (rad) RMS residuals;Sector;;rad", 14, 0, 14, 40, 0, 40);
 
    hprofGlobalPositionCSC = fs->make<TH2F>(
        "hprofGlobalPositionCSC", "Global CSC position (cm) absolute MEAN residuals;Sector;;cm", 36, 0, 36, 36, 0, 36);
    hprofGlobalAngleCSC = fs->make<TH2F>(
        "hprofGlobalAngleCSC", "Global CSC angle (rad) absolute MEAN residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
    hprofGlobalPositionRmsCSC = fs->make<TH2F>(
        "hprofGlobalPositionRmsCSC", "Global CSC position (cm) RMS residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
    hprofGlobalAngleRmsCSC = fs->make<TH2F>(
        "hprofGlobalAngleRmsCSC", "Global CSC angle (rad) RMS residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
    hprofLocalPositionCSC = fs->make<TH2F>(
        "hprofLocalPositionCSC", "Local CSC position (cm) absolute MEAN residuals;Sector;;cm", 36, 0, 36, 36, 0, 36);
    hprofLocalAngleCSC = fs->make<TH2F>(
        "hprofLocalAngleCSC", "Local CSC angle (rad) absolute MEAN residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
    hprofLocalPositionRmsCSC = fs->make<TH2F>(
        "hprofLocalPositionRmsCSC", "Local CSC position (cm) RMS residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
    hprofLocalAngleRmsCSC = fs->make<TH2F>(
        "hprofLocalAngleRmsCSC", "Local CSC angle (rad) RMS residuals;Sector;;rad", 36, 0, 36, 36, 0, 36);
 
    // histos options
    Float_t labelSize = 0.025;
    hprofGlobalPositionDT->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalAngleDT->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalPositionRmsDT->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalAngleRmsDT->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalPositionDT->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalAngleDT->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalPositionRmsDT->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalAngleRmsDT->GetYaxis()->SetLabelSize(labelSize);
 
    hprofGlobalPositionCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalAngleCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalPositionRmsCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofGlobalAngleRmsCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalPositionCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalAngleCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalPositionRmsCSC->GetYaxis()->SetLabelSize(labelSize);
    hprofLocalAngleRmsCSC->GetYaxis()->SetLabelSize(labelSize);
 
    char binLabel[32];
    for (int i = 1; i < 15; i++) {
      snprintf(binLabel, sizeof(binLabel), "Sec-%d", i);
      hprofGlobalPositionDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalAngleDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalPositionRmsDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalAngleRmsDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalPositionDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalAngleDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalPositionRmsDT->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalAngleRmsDT->GetXaxis()->SetBinLabel(i, binLabel);
    }
 
    for (int i = 1; i < 37; i++) {
      snprintf(binLabel, sizeof(binLabel), "Ch-%d", i);
      hprofGlobalPositionCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalAngleCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalPositionRmsCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofGlobalAngleRmsCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalPositionCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalAngleCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalPositionRmsCSC->GetXaxis()->SetBinLabel(i, binLabel);
      hprofLocalAngleRmsCSC->GetXaxis()->SetBinLabel(i, binLabel);
    }
  }
}

References doGBplots, doResplots, doSAplots, fs, hGBChi2, hGBChi2_Barrel, hGBChi2_Endcap, hGBInvM, hGBInvM_Barrel, hGBInvM_Endcap, hGBInvM_Overlap, hGBinvPTres, hGBinvPTvsEta, hGBinvPTvsNhits, hGBinvPTvsPhi, hGBNhits, hGBNhits_Barrel, hGBNhits_Endcap, hGBNmuons, hGBNmuons_Barrel, hGBNmuons_Endcap, hGBPhivsEta, hGBPTDiff, hGBPTDiffvsEta, hGBPTDiffvsPhi, hGBPTRec, hGBPTRec_Barrel, hGBPTRec_Endcap, hGBPTres, hGBPTres_Barrel, hGBPTres_Endcap, hGBPTvsEta, hGBPTvsPhi, hprofGlobalAngleCSC, hprofGlobalAngleDT, hprofGlobalAngleRmsCSC, hprofGlobalAngleRmsDT, hprofGlobalPhiCSC, hprofGlobalPhiDT, hprofGlobalPositionCSC, hprofGlobalPositionDT, hprofGlobalPositionRmsCSC, hprofGlobalPositionRmsDT, hprofGlobalRCSC, hprofGlobalRPhiCSC, hprofGlobalRPhiDT, hprofGlobalThetaCSC, hprofGlobalThetaDT, hprofGlobalZDT, hprofLocalAngleCSC, hprofLocalAngleDT, hprofLocalAngleRmsCSC, hprofLocalAngleRmsDT, hprofLocalPhiCSC, hprofLocalPhiDT, hprofLocalPositionCSC, hprofLocalPositionDT, hprofLocalPositionRmsCSC, hprofLocalPositionRmsDT, hprofLocalThetaCSC, hprofLocalThetaDT, hprofLocalXCSC, hprofLocalXDT, hprofLocalYCSC, hprofLocalYDT, hResidualGlobalPhiCSC, hResidualGlobalPhiCSC_ME, hResidualGlobalPhiDT, hResidualGlobalPhiDT_MB, hResidualGlobalPhiDT_W, hResidualGlobalRCSC, hResidualGlobalRCSC_ME, hResidualGlobalRPhiCSC, hResidualGlobalRPhiCSC_ME, hResidualGlobalRPhiDT, hResidualGlobalRPhiDT_MB, hResidualGlobalRPhiDT_W, hResidualGlobalThetaCSC, hResidualGlobalThetaCSC_ME, hResidualGlobalThetaDT, hResidualGlobalThetaDT_MB, hResidualGlobalThetaDT_W, hResidualGlobalZDT, hResidualGlobalZDT_MB, hResidualGlobalZDT_W, hResidualLocalPhiCSC, hResidualLocalPhiCSC_ME, hResidualLocalPhiDT, hResidualLocalPhiDT_MB, hResidualLocalPhiDT_W, hResidualLocalThetaCSC, hResidualLocalThetaCSC_ME, hResidualLocalThetaDT, hResidualLocalThetaDT_MB, hResidualLocalThetaDT_W, hResidualLocalXCSC, hResidualLocalXCSC_ME, hResidualLocalXDT, hResidualLocalXDT_MB, hResidualLocalXDT_W, hResidualLocalYCSC, hResidualLocalYCSC_ME, hResidualLocalYDT, hResidualLocalYDT_MB, hResidualLocalYDT_W, hSAChi2, hSAChi2_Barrel, hSAChi2_Endcap, hSAInvM, hSAInvM_Barrel, hSAInvM_Endcap, hSAInvM_Overlap, hSAinvPTres, hSAinvPTvsEta, hSAinvPTvsNhits, hSAinvPTvsPhi, hSANhits, hSANhits_Barrel, hSANhits_Endcap, hSANmuons, hSANmuons_Barrel, hSANmuons_Endcap, hSAPhivsEta, hSAPTDiff, hSAPTDiffvsEta, hSAPTDiffvsPhi, hSAPTRec, hSAPTRec_Barrel, hSAPTRec_Endcap, hSAPTres, hSAPTres_Barrel, hSAPTres_Endcap, hSAPTvsEta, hSAPTvsPhi, hSimInvM, hSimInvM_Barrel, hSimInvM_Endcap, hSimInvM_Overlap, hSimNmuons, hSimNmuons_Barrel, hSimNmuons_Endcap, hSimPhivsEta, hSimPT, hSimPT_Barrel, hSimPT_Endcap, hSimPTvsEta, hSimPTvsPhi, mps_fire::i, createfilelist::int, invMassRangeMax, invMassRangeMin, TFileService::make(), ptRangeMax, ptRangeMin, and theDataType.

doMatching()

RecHitVector MuonAlignmentAnalyzer::doMatching ( const reco::Track &  staTrack, edm::Handle< DTRecSegment4DCollection > &  all4DSegmentsDT, edm::Handle< CSCSegmentCollection > &  all4DSegmentsCSC, intDVector *  indexCollectionDT, intDVector *  indexCollectionCSC, edm::ESHandle< GlobalTrackingGeometry > &  theTrackingGeometry  )

private

Definition at line 2466 of file MuonAlignmentAnalyzer.cc.

                                                                                                         {
  DTRecSegment4DCollection::const_iterator segmentDT;
  CSCSegmentCollection::const_iterator segmentCSC;
 
  std::vector<int> positionDT;
  std::vector<int> positionCSC;
  RecHitVector my4DTrack;
 
  //Loop over the hits of the track
  for (int counter = 0; counter != staTrack.numberOfValidHits() - 1; counter++) {
    TrackingRecHitRef myRef = staTrack.recHit(counter);
    const TrackingRecHit *rechit = myRef.get();
    const GeomDet *geomDet = theTrackingGeometry->idToDet(rechit->geographicalId());
 
    //It's a DT Hit
    if (geomDet->subDetector() == GeomDetEnumerators::DT) {
      //Take the layer associated to this hit
      DTLayerId myLayer(rechit->geographicalId().rawId());
 
      int NumberOfDTSegment = 0;
      //Loop over segments
      for (segmentDT = all4DSegmentsDT->begin(); segmentDT != all4DSegmentsDT->end(); ++segmentDT) {
        //By default the chamber associated to this Segment is new
        bool isNewChamber = true;
 
        //Loop over segments already included in the vector of segments in the actual track
        for (std::vector<int>::iterator positionIt = positionDT.begin(); positionIt != positionDT.end(); positionIt++) {
          //If this segment has been used before isNewChamber = false
          if (NumberOfDTSegment == *positionIt)
            isNewChamber = false;
        }
 
        //Loop over vectors of segments associated to previous tracks
        for (std::vector<std::vector<int> >::iterator collect = indexCollectionDT->begin();
             collect != indexCollectionDT->end();
             ++collect) {
          //Loop over segments associated to a track
          for (std::vector<int>::iterator positionIt = (*collect).begin(); positionIt != (*collect).end();
               positionIt++) {
            //If this segment was used in a previos track then isNewChamber = false
            if (NumberOfDTSegment == *positionIt)
              isNewChamber = false;
          }
        }
 
        //If the chamber is new
        if (isNewChamber) {
          DTChamberId myChamber((*segmentDT).geographicalId().rawId());
          //If the layer of the hit belongs to the chamber of the 4D Segment
          if (myLayer.wheel() == myChamber.wheel() && myLayer.station() == myChamber.station() &&
              myLayer.sector() == myChamber.sector()) {
            //push position of the segment and tracking rechit
            positionDT.push_back(NumberOfDTSegment);
            my4DTrack.push_back((TrackingRecHit *)&(*segmentDT));
          }
        }
        NumberOfDTSegment++;
      }
      //In case is a CSC
    } else if (geomDet->subDetector() == GeomDetEnumerators::CSC) {
      //Take the layer associated to this hit
      CSCDetId myLayer(rechit->geographicalId().rawId());
 
      int NumberOfCSCSegment = 0;
      //Loop over 4Dsegments
      for (segmentCSC = all4DSegmentsCSC->begin(); segmentCSC != all4DSegmentsCSC->end(); segmentCSC++) {
        //By default the chamber associated to the segment is new
        bool isNewChamber = true;
 
        //Loop over segments in the current track
        for (std::vector<int>::iterator positionIt = positionCSC.begin(); positionIt != positionCSC.end();
             positionIt++) {
          //If this segment has been used then newchamber = false
          if (NumberOfCSCSegment == *positionIt)
            isNewChamber = false;
        }
        //Loop over vectors of segments in previous tracks
        for (std::vector<std::vector<int> >::iterator collect = indexCollectionCSC->begin();
             collect != indexCollectionCSC->end();
             ++collect) {
          //Loop over segments in a track
          for (std::vector<int>::iterator positionIt = (*collect).begin(); positionIt != (*collect).end();
               positionIt++) {
            //If the segment was used in a previous track isNewChamber = false
            if (NumberOfCSCSegment == *positionIt)
              isNewChamber = false;
          }
        }
        //If the chamber is new
        if (isNewChamber) {
          CSCDetId myChamber((*segmentCSC).geographicalId().rawId());
          //If the chambers are the same
          if (myLayer.chamberId() == myChamber.chamberId()) {
            //push
            positionCSC.push_back(NumberOfCSCSegment);
            my4DTrack.push_back((TrackingRecHit *)&(*segmentCSC));
          }
        }
        NumberOfCSCSegment++;
      }
    }
  }
 
  indexCollectionDT->push_back(positionDT);
  indexCollectionCSC->push_back(positionCSC);
 
  return my4DTrack;
}

References GeomDetEnumerators::CSC, GeomDetEnumerators::DT, TrackingRecHit::geographicalId(), edm::Ref< C, T, F >::get(), GlobalTrackingGeometry::idToDet(), reco::TrackBase::numberOfValidHits(), DetId::rawId(), reco::Track::recHit(), GeomDet::subDetector(), and trackerHitRTTI::vector.

Referenced by analyze().

endJob()

void MuonAlignmentAnalyzer::endJob ( void  )

overridevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 1011 of file MuonAlignmentAnalyzer.cc.

                                   {
  edm::LogInfo("MuonAlignmentAnalyzer") << "----------------- " << std::endl << std::endl;
 
  if (theDataType == "SimData")
    edm::LogInfo("MuonAlignmentAnalyzer") << "Number of Sim tracks: " << numberOfSimTracks << std::endl << std::endl;
 
  if (doSAplots)
    edm::LogInfo("MuonAlignmentAnalyzer") << "Number of SA Reco tracks: " << numberOfSARecTracks << std::endl
                                          << std::endl;
 
  if (doGBplots)
    edm::LogInfo("MuonAlignmentAnalyzer") << "Number of GB Reco tracks: " << numberOfGBRecTracks << std::endl
                                          << std::endl;
 
  if (doResplots) {
    //  delete thePropagator;
 
    edm::LogInfo("MuonAlignmentAnalyzer") << "Number of Hits considered for residuals: " << numberOfHits << std::endl
                                          << std::endl;
 
    char binLabel[40];
 
    for (unsigned int i = 0; i < unitsLocalX.size(); i++) {
      TString nameHistoLocalX = unitsLocalX[i]->GetName();
 
      TString nameHistoLocalPhi = unitsLocalPhi[i]->GetName();
 
      TString nameHistoLocalTheta = unitsLocalTheta[i]->GetName();
 
      TString nameHistoLocalY = unitsLocalY[i]->GetName();
 
      TString nameHistoGlobalRPhi = unitsGlobalRPhi[i]->GetName();
 
      TString nameHistoGlobalPhi = unitsGlobalPhi[i]->GetName();
 
      TString nameHistoGlobalTheta = unitsGlobalTheta[i]->GetName();
 
      TString nameHistoGlobalRZ = unitsGlobalRZ[i]->GetName();
 
      if (nameHistoLocalX.Contains("MB"))  // HistoLocalX DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoLocalX, "ResidualLocalX_W%dMB%1dS%d", &wheel, &station, &sector);
 
        Int_t nstation = station - 1;
        Int_t nwheel = wheel + 2;
 
        Double_t MeanRPhi = unitsLocalX[i]->GetMean();
        Double_t ErrorRPhi = unitsLocalX[i]->GetMeanError();
 
        Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
        snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
        hprofLocalXDT->SetMarkerStyle(21);
        hprofLocalXDT->SetMarkerColor(kRed);
        hprofLocalXDT->SetBinContent(xbin, MeanRPhi);
        hprofLocalXDT->SetBinError(xbin, ErrorRPhi);
        hprofLocalXDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = 1 + nwheel * 8 + nstation * 2;
        hprofLocalPositionDT->SetBinContent(sector, ybin, fabs(MeanRPhi));
        snprintf(binLabel, sizeof(binLabel), "MB%d/%d_LocalX", wheel, station);
        hprofLocalPositionDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalPositionRmsDT->SetBinContent(sector, ybin, ErrorRPhi);
        hprofLocalPositionRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoLocalX.Contains("ME"))  // HistoLocalX CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoLocalX, "ResidualLocalX_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanRPhi = unitsLocalX[i]->GetMean();
        Double_t ErrorRPhi = unitsLocalX[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofLocalXCSC->SetMarkerStyle(21);
        hprofLocalXCSC->SetMarkerColor(kRed);
        hprofLocalXCSC->SetBinContent(xbin, MeanRPhi);
        hprofLocalXCSC->SetBinError(xbin, ErrorRPhi);
        hprofLocalXCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin - 1;
        hprofLocalPositionCSC->SetBinContent(chamber, ybin, fabs(MeanRPhi));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_LocalX", station, ring);
        hprofLocalPositionCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalPositionRmsCSC->SetBinContent(chamber, ybin, ErrorRPhi);
        hprofLocalPositionRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoLocalTheta.Contains("MB"))  // HistoLocalTheta DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoLocalTheta, "ResidualLocalTheta_W%dMB%1dS%d", &wheel, &station, &sector);
 
        if (station != 4) {
          Int_t nstation = station - 1;
          Int_t nwheel = wheel + 2;
 
          Double_t MeanTheta = unitsLocalTheta[i]->GetMean();
          Double_t ErrorTheta = unitsLocalTheta[i]->GetMeanError();
 
          Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
          snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
          hprofLocalThetaDT->SetBinContent(xbin, MeanTheta);
          hprofLocalThetaDT->SetBinError(xbin, ErrorTheta);
          hprofLocalThetaDT->SetMarkerStyle(21);
          hprofLocalThetaDT->SetMarkerColor(kRed);
          hprofLocalThetaDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
          Int_t ybin = 2 + nwheel * 8 + nstation * 2;
          hprofLocalAngleDT->SetBinContent(sector, ybin, fabs(MeanTheta));
          snprintf(binLabel, sizeof(binLabel), "MB%d/%d_LocalTheta", wheel, station);
          hprofLocalAngleDT->GetYaxis()->SetBinLabel(ybin, binLabel);
          hprofLocalAngleRmsDT->SetBinContent(sector, ybin, ErrorTheta);
          hprofLocalAngleRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        }
      }
 
      if (nameHistoLocalPhi.Contains("MB"))  // HistoLocalPhi DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoLocalPhi, "ResidualLocalPhi_W%dMB%1dS%d", &wheel, &station, &sector);
 
        Int_t nstation = station - 1;
        Int_t nwheel = wheel + 2;
 
        Double_t MeanPhi = unitsLocalPhi[i]->GetMean();
        Double_t ErrorPhi = unitsLocalPhi[i]->GetMeanError();
 
        Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
        snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
        hprofLocalPhiDT->SetBinContent(xbin, MeanPhi);
        hprofLocalPhiDT->SetBinError(xbin, ErrorPhi);
        hprofLocalPhiDT->SetMarkerStyle(21);
        hprofLocalPhiDT->SetMarkerColor(kRed);
        hprofLocalPhiDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = 1 + nwheel * 8 + nstation * 2;
        hprofLocalAngleDT->SetBinContent(sector, ybin, fabs(MeanPhi));
        snprintf(binLabel, sizeof(binLabel), "MB%d/%d_LocalPhi", wheel, station);
        hprofLocalAngleDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalAngleRmsDT->SetBinContent(sector, ybin, ErrorPhi);
        hprofLocalAngleRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoLocalPhi.Contains("ME"))  // HistoLocalPhi CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoLocalPhi, "ResidualLocalPhi_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanPhi = unitsLocalPhi[i]->GetMean();
        Double_t ErrorPhi = unitsLocalPhi[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofLocalPhiCSC->SetMarkerStyle(21);
        hprofLocalPhiCSC->SetMarkerColor(kRed);
        hprofLocalPhiCSC->SetBinContent(xbin, MeanPhi);
        hprofLocalPhiCSC->SetBinError(xbin, ErrorPhi);
        hprofLocalPhiCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin - 1;
        hprofLocalAngleCSC->SetBinContent(chamber, ybin, fabs(MeanPhi));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_LocalPhi", station, ring);
        hprofLocalAngleCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalAngleRmsCSC->SetBinContent(chamber, ybin, ErrorPhi);
        hprofLocalAngleRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoLocalTheta.Contains("ME"))  // HistoLocalTheta CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoLocalTheta, "ResidualLocalTheta_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanTheta = unitsLocalTheta[i]->GetMean();
        Double_t ErrorTheta = unitsLocalTheta[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofLocalThetaCSC->SetMarkerStyle(21);
        hprofLocalThetaCSC->SetMarkerColor(kRed);
        hprofLocalThetaCSC->SetBinContent(xbin, MeanTheta);
        hprofLocalThetaCSC->SetBinError(xbin, ErrorTheta);
        hprofLocalThetaCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin;
        hprofLocalAngleCSC->SetBinContent(chamber, ybin, fabs(MeanTheta));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_LocalTheta", station, ring);
        hprofLocalAngleCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalAngleRmsCSC->SetBinContent(chamber, ybin, ErrorTheta);
        hprofLocalAngleRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoLocalY.Contains("MB"))  // HistoLocalY DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoLocalY, "ResidualLocalY_W%dMB%1dS%d", &wheel, &station, &sector);
 
        if (station != 4) {
          Int_t nstation = station - 1;
          Int_t nwheel = wheel + 2;
 
          Double_t MeanZ = unitsLocalY[i]->GetMean();
          Double_t ErrorZ = unitsLocalY[i]->GetMeanError();
 
          Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
          snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
          hprofLocalYDT->SetMarkerStyle(21);
          hprofLocalYDT->SetMarkerColor(kRed);
          hprofLocalYDT->SetBinContent(xbin, MeanZ);
          hprofLocalYDT->SetBinError(xbin, ErrorZ);
          hprofLocalYDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
          Int_t ybin = 2 + nwheel * 8 + nstation * 2;
          hprofLocalPositionDT->SetBinContent(sector, ybin, fabs(MeanZ));
          snprintf(binLabel, sizeof(binLabel), "MB%d/%d_LocalY", wheel, station);
          hprofLocalPositionDT->GetYaxis()->SetBinLabel(ybin, binLabel);
          hprofLocalPositionRmsDT->SetBinContent(sector, ybin, ErrorZ);
          hprofLocalPositionRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        }
      }
 
      if (nameHistoLocalY.Contains("ME"))  // HistoLocalY CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoLocalY, "ResidualLocalY_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanR = unitsLocalY[i]->GetMean();
        Double_t ErrorR = unitsLocalY[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofLocalYCSC->SetMarkerStyle(21);
        hprofLocalYCSC->SetMarkerColor(kRed);
        hprofLocalYCSC->SetBinContent(xbin, MeanR);
        hprofLocalYCSC->SetBinError(xbin, ErrorR);
        hprofLocalYCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin;
        hprofLocalPositionCSC->SetBinContent(chamber, ybin, fabs(MeanR));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_LocalY", station, ring);
        hprofLocalPositionCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofLocalPositionRmsCSC->SetBinContent(chamber, ybin, ErrorR);
        hprofLocalPositionRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalRPhi.Contains("MB"))  // HistoGlobalRPhi DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoGlobalRPhi, "ResidualGlobalRPhi_W%dMB%1dS%d", &wheel, &station, &sector);
 
        Int_t nstation = station - 1;
        Int_t nwheel = wheel + 2;
 
        Double_t MeanRPhi = unitsGlobalRPhi[i]->GetMean();
        Double_t ErrorRPhi = unitsGlobalRPhi[i]->GetMeanError();
 
        Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
        snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
        hprofGlobalRPhiDT->SetMarkerStyle(21);
        hprofGlobalRPhiDT->SetMarkerColor(kRed);
        hprofGlobalRPhiDT->SetBinContent(xbin, MeanRPhi);
        hprofGlobalRPhiDT->SetBinError(xbin, ErrorRPhi);
        hprofGlobalRPhiDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = 1 + nwheel * 8 + nstation * 2;
        hprofGlobalPositionDT->SetBinContent(sector, ybin, fabs(MeanRPhi));
        snprintf(binLabel, sizeof(binLabel), "MB%d/%d_GlobalRPhi", wheel, station);
        hprofGlobalPositionDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalPositionRmsDT->SetBinContent(sector, ybin, ErrorRPhi);
        hprofGlobalPositionRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalRPhi.Contains("ME"))  // HistoGlobalRPhi CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoGlobalRPhi, "ResidualGlobalRPhi_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanRPhi = unitsGlobalRPhi[i]->GetMean();
        Double_t ErrorRPhi = unitsGlobalRPhi[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofGlobalRPhiCSC->SetMarkerStyle(21);
        hprofGlobalRPhiCSC->SetMarkerColor(kRed);
        hprofGlobalRPhiCSC->SetBinContent(xbin, MeanRPhi);
        hprofGlobalRPhiCSC->SetBinError(xbin, ErrorRPhi);
        hprofGlobalRPhiCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin - 1;
        hprofGlobalPositionCSC->SetBinContent(chamber, ybin, fabs(MeanRPhi));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_GlobalRPhi", station, ring);
        hprofGlobalPositionCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalPositionRmsCSC->SetBinContent(chamber, ybin, ErrorRPhi);
        hprofGlobalPositionRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalTheta.Contains("MB"))  // HistoGlobalRTheta DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoGlobalTheta, "ResidualGlobalTheta_W%dMB%1dS%d", &wheel, &station, &sector);
 
        if (station != 4) {
          Int_t nstation = station - 1;
          Int_t nwheel = wheel + 2;
 
          Double_t MeanTheta = unitsGlobalTheta[i]->GetMean();
          Double_t ErrorTheta = unitsGlobalTheta[i]->GetMeanError();
 
          Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
          snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
          hprofGlobalThetaDT->SetBinContent(xbin, MeanTheta);
          hprofGlobalThetaDT->SetBinError(xbin, ErrorTheta);
          hprofGlobalThetaDT->SetMarkerStyle(21);
          hprofGlobalThetaDT->SetMarkerColor(kRed);
          hprofGlobalThetaDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
          Int_t ybin = 2 + nwheel * 8 + nstation * 2;
          hprofGlobalAngleDT->SetBinContent(sector, ybin, fabs(MeanTheta));
          snprintf(binLabel, sizeof(binLabel), "MB%d/%d_GlobalTheta", wheel, station);
          hprofGlobalAngleDT->GetYaxis()->SetBinLabel(ybin, binLabel);
          hprofGlobalAngleRmsDT->SetBinContent(sector, ybin, ErrorTheta);
          hprofGlobalAngleRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        }
      }
 
      if (nameHistoGlobalPhi.Contains("MB"))  // HistoGlobalPhi DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoGlobalPhi, "ResidualGlobalPhi_W%dMB%1dS%d", &wheel, &station, &sector);
 
        Int_t nstation = station - 1;
        Int_t nwheel = wheel + 2;
 
        Double_t MeanPhi = unitsGlobalPhi[i]->GetMean();
        Double_t ErrorPhi = unitsGlobalPhi[i]->GetMeanError();
 
        Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
        snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
        hprofGlobalPhiDT->SetBinContent(xbin, MeanPhi);
        hprofGlobalPhiDT->SetBinError(xbin, ErrorPhi);
        hprofGlobalPhiDT->SetMarkerStyle(21);
        hprofGlobalPhiDT->SetMarkerColor(kRed);
        hprofGlobalPhiDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = 1 + nwheel * 8 + nstation * 2;
        hprofGlobalAngleDT->SetBinContent(sector, ybin, fabs(MeanPhi));
        snprintf(binLabel, sizeof(binLabel), "MB%d/%d_GlobalPhi", wheel, station);
        hprofGlobalAngleDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalAngleRmsDT->SetBinContent(sector, ybin, ErrorPhi);
        hprofGlobalAngleRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalPhi.Contains("ME"))  // HistoGlobalPhi CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoGlobalPhi, "ResidualGlobalPhi_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanPhi = unitsGlobalPhi[i]->GetMean();
        Double_t ErrorPhi = unitsGlobalPhi[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofGlobalPhiCSC->SetMarkerStyle(21);
        hprofGlobalPhiCSC->SetMarkerColor(kRed);
        hprofGlobalPhiCSC->SetBinContent(xbin, MeanPhi);
        hprofGlobalPhiCSC->SetBinError(xbin, ErrorPhi);
        hprofGlobalPhiCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin - 1;
        hprofGlobalAngleCSC->SetBinContent(chamber, ybin, fabs(MeanPhi));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_GlobalPhi", station, ring);
        hprofGlobalAngleCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalAngleRmsCSC->SetBinContent(chamber, ybin, ErrorPhi);
        hprofGlobalAngleRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalTheta.Contains("ME"))  // HistoGlobalTheta CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoGlobalTheta, "ResidualGlobalTheta_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanTheta = unitsGlobalTheta[i]->GetMean();
        Double_t ErrorTheta = unitsGlobalTheta[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofGlobalThetaCSC->SetMarkerStyle(21);
        hprofGlobalThetaCSC->SetMarkerColor(kRed);
        hprofGlobalThetaCSC->SetBinContent(xbin, MeanTheta);
        hprofGlobalThetaCSC->SetBinError(xbin, ErrorTheta);
        hprofGlobalThetaCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin;
        hprofGlobalAngleCSC->SetBinContent(chamber, ybin, fabs(MeanTheta));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_GlobalTheta", station, ring);
        hprofGlobalAngleCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalAngleRmsCSC->SetBinContent(chamber, ybin, ErrorTheta);
        hprofGlobalAngleRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
      if (nameHistoGlobalRZ.Contains("MB"))  // HistoGlobalZ DT
      {
        int wheel, station, sector;
 
        sscanf(nameHistoGlobalRZ, "ResidualGlobalZ_W%dMB%1dS%d", &wheel, &station, &sector);
 
        if (station != 4) {
          Int_t nstation = station - 1;
          Int_t nwheel = wheel + 2;
 
          Double_t MeanZ = unitsGlobalRZ[i]->GetMean();
          Double_t ErrorZ = unitsGlobalRZ[i]->GetMeanError();
 
          Int_t xbin = sector + 14 * nstation + 14 * 4 * nwheel;
 
          snprintf(binLabel, sizeof(binLabel), "MB%d/%dS%d", wheel, station, sector);
 
          hprofGlobalZDT->SetMarkerStyle(21);
          hprofGlobalZDT->SetMarkerColor(kRed);
 
          hprofGlobalZDT->SetBinContent(xbin, MeanZ);
          hprofGlobalZDT->SetBinError(xbin, ErrorZ);
          hprofGlobalZDT->GetXaxis()->SetBinLabel(xbin, binLabel);
 
          Int_t ybin = 2 + nwheel * 8 + nstation * 2;
          hprofGlobalPositionDT->SetBinContent(sector, ybin, fabs(MeanZ));
          snprintf(binLabel, sizeof(binLabel), "MB%d/%d_GlobalZ", wheel, station);
          hprofGlobalPositionDT->GetYaxis()->SetBinLabel(ybin, binLabel);
          hprofGlobalPositionRmsDT->SetBinContent(sector, ybin, ErrorZ);
          hprofGlobalPositionRmsDT->GetYaxis()->SetBinLabel(ybin, binLabel);
        }
      }
 
      if (nameHistoGlobalRZ.Contains("ME"))  // HistoGlobalR CSC
      {
        int station, ring, chamber;
 
        sscanf(nameHistoGlobalRZ, "ResidualGlobalR_ME%dR%1dC%d", &station, &ring, &chamber);
 
        Double_t MeanR = unitsGlobalRZ[i]->GetMean();
        Double_t ErrorR = unitsGlobalRZ[i]->GetMeanError();
 
        Int_t xbin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          xbin = ring;
        if (station > 0)
          xbin = xbin + 9;
        else
          xbin = 10 - xbin;
 
        // To avoid holes in xAxis, I can't imagine right now a simpler way...
        if (xbin < 5)
          xbin = 18 * (((Int_t)(xbin / 3)) * 2 + (Int_t)(xbin / 2)) + chamber;
        else if (xbin < 6)
          xbin = 108 + chamber;
        else if (xbin < 14)
          xbin = 126 + (xbin - 6) * 36 + chamber;
        else if (xbin < 18)
          xbin = 414 + 18 * (((Int_t)(xbin - 13) / 3) * 2 + ((Int_t)(xbin - 13) / 2)) + chamber;
        else
          xbin = 522 + chamber;
 
        snprintf(binLabel, sizeof(binLabel), "ME%d/%dC%d", station, ring, chamber);
 
        hprofGlobalRCSC->SetMarkerStyle(21);
        hprofGlobalRCSC->SetMarkerColor(kRed);
        hprofGlobalRCSC->SetBinContent(xbin, MeanR);
        hprofGlobalRCSC->SetBinError(xbin, ErrorR);
        hprofGlobalRCSC->GetXaxis()->SetBinLabel(xbin, binLabel);
 
        Int_t ybin = abs(station) * 2 + ring;
        if (abs(station) == 1)
          ybin = ring;
        if (station > 0)
          ybin = ybin + 9;
        else
          ybin = 10 - ybin;
        ybin = 2 * ybin;
        hprofGlobalPositionCSC->SetBinContent(chamber, ybin, fabs(MeanR));
        snprintf(binLabel, sizeof(binLabel), "ME%d/%d_GlobalR", station, ring);
        hprofGlobalPositionCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
        hprofGlobalPositionRmsCSC->SetBinContent(chamber, ybin, ErrorR);
        hprofGlobalPositionRmsCSC->GetYaxis()->SetBinLabel(ybin, binLabel);
      }
 
    }  // for in histos
 
  }  // doResPlots
}

References funct::abs(), relativeConstraints::chamber, doGBplots, doResplots, doSAplots, hprofGlobalAngleCSC, hprofGlobalAngleDT, hprofGlobalAngleRmsCSC, hprofGlobalAngleRmsDT, hprofGlobalPhiCSC, hprofGlobalPhiDT, hprofGlobalPositionCSC, hprofGlobalPositionDT, hprofGlobalPositionRmsCSC, hprofGlobalPositionRmsDT, hprofGlobalRCSC, hprofGlobalRPhiCSC, hprofGlobalRPhiDT, hprofGlobalThetaCSC, hprofGlobalThetaDT, hprofGlobalZDT, hprofLocalAngleCSC, hprofLocalAngleDT, hprofLocalAngleRmsCSC, hprofLocalAngleRmsDT, hprofLocalPhiCSC, hprofLocalPhiDT, hprofLocalPositionCSC, hprofLocalPositionDT, hprofLocalPositionRmsCSC, hprofLocalPositionRmsDT, hprofLocalThetaCSC, hprofLocalThetaDT, hprofLocalXCSC, hprofLocalXDT, hprofLocalYCSC, hprofLocalYDT, mps_fire::i, VtxSmearedParameters_cfi::MeanZ, numberOfGBRecTracks, numberOfHits, numberOfSARecTracks, numberOfSimTracks, relativeConstraints::ring, relativeConstraints::station, theDataType, unitsGlobalPhi, unitsGlobalRPhi, unitsGlobalRZ, unitsGlobalTheta, unitsLocalPhi, unitsLocalTheta, unitsLocalX, unitsLocalY, and makeMuonMisalignmentScenario::wheel.

Referenced by o2olib.O2ORunMgr::executeJob().

Member Data Documentation

detectorCollection

std::vector<long> MuonAlignmentAnalyzer::detectorCollection

private

Definition at line 263 of file MuonAlignmentAnalyzer.h.

Referenced by analyze().

doGBplots

bool MuonAlignmentAnalyzer::doGBplots

private

Definition at line 82 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), beginJob(), endJob(), and MuonAlignmentAnalyzer().

doResplots

bool MuonAlignmentAnalyzer::doResplots

private

Definition at line 82 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), beginJob(), endJob(), and MuonAlignmentAnalyzer().

doSAplots

bool MuonAlignmentAnalyzer::doSAplots

private

Definition at line 82 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), beginJob(), endJob(), and MuonAlignmentAnalyzer().

fs

edm::Service<TFileService> MuonAlignmentAnalyzer::fs

private

Definition at line 69 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBChi2

TH1F* MuonAlignmentAnalyzer::hGBChi2

private

Definition at line 106 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBChi2_Barrel

TH1F* MuonAlignmentAnalyzer::hGBChi2_Barrel

private

Definition at line 108 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBChi2_Endcap

TH1F* MuonAlignmentAnalyzer::hGBChi2_Endcap

private

Definition at line 110 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBInvM

TH1F* MuonAlignmentAnalyzer::hGBInvM

private

Definition at line 114 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBInvM_Barrel

TH1F* MuonAlignmentAnalyzer::hGBInvM_Barrel

private

Definition at line 118 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBInvM_Endcap

TH1F* MuonAlignmentAnalyzer::hGBInvM_Endcap

private

Definition at line 122 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBInvM_Overlap

TH1F* MuonAlignmentAnalyzer::hGBInvM_Overlap

private

Definition at line 127 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBinvPTres

TH1F* MuonAlignmentAnalyzer::hGBinvPTres

private

Definition at line 157 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBinvPTvsEta

TH2F* MuonAlignmentAnalyzer::hGBinvPTvsEta

private

Definition at line 169 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBinvPTvsNhits

TH2F* MuonAlignmentAnalyzer::hGBinvPTvsNhits

private

Definition at line 174 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBinvPTvsPhi

TH2F* MuonAlignmentAnalyzer::hGBinvPTvsPhi

private

Definition at line 170 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNhits

TH1F* MuonAlignmentAnalyzer::hGBNhits

private

Definition at line 98 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNhits_Barrel

TH1F* MuonAlignmentAnalyzer::hGBNhits_Barrel

private

Definition at line 99 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNhits_Endcap

TH1F* MuonAlignmentAnalyzer::hGBNhits_Endcap

private

Definition at line 100 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNmuons

TH1F* MuonAlignmentAnalyzer::hGBNmuons

private

Definition at line 87 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNmuons_Barrel

TH1F* MuonAlignmentAnalyzer::hGBNmuons_Barrel

private

Definition at line 90 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBNmuons_Endcap

TH1F* MuonAlignmentAnalyzer::hGBNmuons_Endcap

private

Definition at line 93 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPhivsEta

TH2F* MuonAlignmentAnalyzer::hGBPhivsEta

private

Definition at line 151 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTDiff

TH1F* MuonAlignmentAnalyzer::hGBPTDiff

private

Definition at line 164 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTDiffvsEta

TH2F* MuonAlignmentAnalyzer::hGBPTDiffvsEta

private

Definition at line 167 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTDiffvsPhi

TH2F* MuonAlignmentAnalyzer::hGBPTDiffvsPhi

private

Definition at line 168 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTRec

TH1F* MuonAlignmentAnalyzer::hGBPTRec

private

Definition at line 133 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTRec_Barrel

TH1F* MuonAlignmentAnalyzer::hGBPTRec_Barrel

private

Definition at line 136 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTRec_Endcap

TH1F* MuonAlignmentAnalyzer::hGBPTRec_Endcap

private

Definition at line 139 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTres

TH1F* MuonAlignmentAnalyzer::hGBPTres

private

Definition at line 156 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTres_Barrel

TH1F* MuonAlignmentAnalyzer::hGBPTres_Barrel

private

Definition at line 160 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTres_Endcap

TH1F* MuonAlignmentAnalyzer::hGBPTres_Endcap

private

Definition at line 161 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTvsEta

TH2F* MuonAlignmentAnalyzer::hGBPTvsEta

private

Definition at line 141 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hGBPTvsPhi

TH2F* MuonAlignmentAnalyzer::hGBPTvsPhi

private

Definition at line 142 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hprofGlobalAngleCSC

TH2F* MuonAlignmentAnalyzer::hprofGlobalAngleCSC

private

Definition at line 234 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalAngleDT

TH2F* MuonAlignmentAnalyzer::hprofGlobalAngleDT

private

Definition at line 242 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalAngleRmsCSC

TH2F* MuonAlignmentAnalyzer::hprofGlobalAngleRmsCSC

private

Definition at line 236 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalAngleRmsDT

TH2F* MuonAlignmentAnalyzer::hprofGlobalAngleRmsDT

private

Definition at line 244 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPhiCSC

TH1F* MuonAlignmentAnalyzer::hprofGlobalPhiCSC

private

Definition at line 259 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPhiDT

TH1F* MuonAlignmentAnalyzer::hprofGlobalPhiDT

private

Definition at line 255 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPositionCSC

TH2F* MuonAlignmentAnalyzer::hprofGlobalPositionCSC

private

Definition at line 233 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPositionDT

TH2F* MuonAlignmentAnalyzer::hprofGlobalPositionDT

private

Definition at line 241 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPositionRmsCSC

TH2F* MuonAlignmentAnalyzer::hprofGlobalPositionRmsCSC

private

Definition at line 235 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalPositionRmsDT

TH2F* MuonAlignmentAnalyzer::hprofGlobalPositionRmsDT

private

Definition at line 243 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalRCSC

TH1F* MuonAlignmentAnalyzer::hprofGlobalRCSC

private

Definition at line 261 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalRPhiCSC

TH1F* MuonAlignmentAnalyzer::hprofGlobalRPhiCSC

private

Definition at line 258 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalRPhiDT

TH1F* MuonAlignmentAnalyzer::hprofGlobalRPhiDT

private

Definition at line 254 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalThetaCSC

TH1F* MuonAlignmentAnalyzer::hprofGlobalThetaCSC

private

Definition at line 260 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalThetaDT

TH1F* MuonAlignmentAnalyzer::hprofGlobalThetaDT

private

Definition at line 256 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofGlobalZDT

TH1F* MuonAlignmentAnalyzer::hprofGlobalZDT

private

Definition at line 257 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalAngleCSC

TH2F* MuonAlignmentAnalyzer::hprofLocalAngleCSC

private

Definition at line 230 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalAngleDT

TH2F* MuonAlignmentAnalyzer::hprofLocalAngleDT

private

Definition at line 238 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalAngleRmsCSC

TH2F* MuonAlignmentAnalyzer::hprofLocalAngleRmsCSC

private

Definition at line 232 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalAngleRmsDT

TH2F* MuonAlignmentAnalyzer::hprofLocalAngleRmsDT

private

Definition at line 240 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPhiCSC

TH1F* MuonAlignmentAnalyzer::hprofLocalPhiCSC

private

Definition at line 251 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPhiDT

TH1F* MuonAlignmentAnalyzer::hprofLocalPhiDT

private

Definition at line 247 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPositionCSC

TH2F* MuonAlignmentAnalyzer::hprofLocalPositionCSC

private

Definition at line 229 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPositionDT

TH2F* MuonAlignmentAnalyzer::hprofLocalPositionDT

private

Definition at line 237 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPositionRmsCSC

TH2F* MuonAlignmentAnalyzer::hprofLocalPositionRmsCSC

private

Definition at line 231 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalPositionRmsDT

TH2F* MuonAlignmentAnalyzer::hprofLocalPositionRmsDT

private

Definition at line 239 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalThetaCSC

TH1F* MuonAlignmentAnalyzer::hprofLocalThetaCSC

private

Definition at line 252 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalThetaDT

TH1F* MuonAlignmentAnalyzer::hprofLocalThetaDT

private

Definition at line 248 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalXCSC

TH1F* MuonAlignmentAnalyzer::hprofLocalXCSC

private

Definition at line 250 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalXDT

TH1F* MuonAlignmentAnalyzer::hprofLocalXDT

private

Definition at line 246 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalYCSC

TH1F* MuonAlignmentAnalyzer::hprofLocalYCSC

private

Definition at line 253 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hprofLocalYDT

TH1F* MuonAlignmentAnalyzer::hprofLocalYDT

private

Definition at line 249 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and endJob().

hResidualGlobalPhiCSC

TH1F* MuonAlignmentAnalyzer::hResidualGlobalPhiCSC

private

Definition at line 212 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalPhiCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalPhiCSC_ME

private

Definition at line 220 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalPhiDT

TH1F* MuonAlignmentAnalyzer::hResidualGlobalPhiDT

private

Definition at line 208 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalPhiDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalPhiDT_MB

private

Definition at line 224 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalPhiDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalPhiDT_W

private

Definition at line 216 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRCSC

TH1F* MuonAlignmentAnalyzer::hResidualGlobalRCSC

private

Definition at line 214 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalRCSC_ME

private

Definition at line 222 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRPhiCSC

TH1F* MuonAlignmentAnalyzer::hResidualGlobalRPhiCSC

private

Definition at line 211 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRPhiCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalRPhiCSC_ME

private

Definition at line 219 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRPhiDT

TH1F* MuonAlignmentAnalyzer::hResidualGlobalRPhiDT

private

Definition at line 207 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRPhiDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalRPhiDT_MB

private

Definition at line 223 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalRPhiDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalRPhiDT_W

private

Definition at line 215 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalThetaCSC

TH1F* MuonAlignmentAnalyzer::hResidualGlobalThetaCSC

private

Definition at line 213 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalThetaCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalThetaCSC_ME

private

Definition at line 221 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalThetaDT

TH1F* MuonAlignmentAnalyzer::hResidualGlobalThetaDT

private

Definition at line 209 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalThetaDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalThetaDT_MB

private

Definition at line 225 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalThetaDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalThetaDT_W

private

Definition at line 217 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalZDT

TH1F* MuonAlignmentAnalyzer::hResidualGlobalZDT

private

Definition at line 210 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalZDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalZDT_MB

private

Definition at line 226 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualGlobalZDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualGlobalZDT_W

private

Definition at line 218 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalPhiCSC

TH1F* MuonAlignmentAnalyzer::hResidualLocalPhiCSC

private

Definition at line 192 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalPhiCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalPhiCSC_ME

private

Definition at line 200 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalPhiDT

TH1F* MuonAlignmentAnalyzer::hResidualLocalPhiDT

private

Definition at line 188 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalPhiDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalPhiDT_MB

private

Definition at line 204 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalPhiDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalPhiDT_W

private

Definition at line 196 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalThetaCSC

TH1F* MuonAlignmentAnalyzer::hResidualLocalThetaCSC

private

Definition at line 193 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalThetaCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalThetaCSC_ME

private

Definition at line 201 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalThetaDT

TH1F* MuonAlignmentAnalyzer::hResidualLocalThetaDT

private

Definition at line 189 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalThetaDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalThetaDT_MB

private

Definition at line 205 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalThetaDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalThetaDT_W

private

Definition at line 197 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalXCSC

TH1F* MuonAlignmentAnalyzer::hResidualLocalXCSC

private

Definition at line 191 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalXCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalXCSC_ME

private

Definition at line 199 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalXDT

TH1F* MuonAlignmentAnalyzer::hResidualLocalXDT

private

Definition at line 187 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalXDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalXDT_MB

private

Definition at line 203 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalXDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalXDT_W

private

Definition at line 195 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalYCSC

TH1F* MuonAlignmentAnalyzer::hResidualLocalYCSC

private

Definition at line 194 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalYCSC_ME

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalYCSC_ME

private

Definition at line 202 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalYDT

TH1F* MuonAlignmentAnalyzer::hResidualLocalYDT

private

Definition at line 190 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalYDT_MB

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalYDT_MB

private

Definition at line 206 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hResidualLocalYDT_W

std::vector<TH1F *> MuonAlignmentAnalyzer::hResidualLocalYDT_W

private

Definition at line 198 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAChi2

TH1F* MuonAlignmentAnalyzer::hSAChi2

private

Definition at line 107 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAChi2_Barrel

TH1F* MuonAlignmentAnalyzer::hSAChi2_Barrel

private

Definition at line 109 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAChi2_Endcap

TH1F* MuonAlignmentAnalyzer::hSAChi2_Endcap

private

Definition at line 111 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAInvM

TH1F* MuonAlignmentAnalyzer::hSAInvM

private

Definition at line 115 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAInvM_Barrel

TH1F* MuonAlignmentAnalyzer::hSAInvM_Barrel

private

Definition at line 119 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAInvM_Endcap

TH1F* MuonAlignmentAnalyzer::hSAInvM_Endcap

private

Definition at line 123 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAInvM_Overlap

TH1F* MuonAlignmentAnalyzer::hSAInvM_Overlap

private

Definition at line 128 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAinvPTres

TH1F* MuonAlignmentAnalyzer::hSAinvPTres

private

Definition at line 155 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAinvPTvsEta

TH2F* MuonAlignmentAnalyzer::hSAinvPTvsEta

private

Definition at line 171 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAinvPTvsNhits

TH2F* MuonAlignmentAnalyzer::hSAinvPTvsNhits

private

Definition at line 173 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAinvPTvsPhi

TH2F* MuonAlignmentAnalyzer::hSAinvPTvsPhi

private

Definition at line 172 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANhits

TH1F* MuonAlignmentAnalyzer::hSANhits

private

Definition at line 101 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANhits_Barrel

TH1F* MuonAlignmentAnalyzer::hSANhits_Barrel

private

Definition at line 102 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANhits_Endcap

TH1F* MuonAlignmentAnalyzer::hSANhits_Endcap

private

Definition at line 103 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANmuons

TH1F* MuonAlignmentAnalyzer::hSANmuons

private

Definition at line 88 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANmuons_Barrel

TH1F* MuonAlignmentAnalyzer::hSANmuons_Barrel

private

Definition at line 91 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSANmuons_Endcap

TH1F* MuonAlignmentAnalyzer::hSANmuons_Endcap

private

Definition at line 94 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPhivsEta

TH2F* MuonAlignmentAnalyzer::hSAPhivsEta

private

Definition at line 150 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTDiff

TH1F* MuonAlignmentAnalyzer::hSAPTDiff

private

Definition at line 163 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTDiffvsEta

TH2F* MuonAlignmentAnalyzer::hSAPTDiffvsEta

private

Definition at line 165 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTDiffvsPhi

TH2F* MuonAlignmentAnalyzer::hSAPTDiffvsPhi

private

Definition at line 166 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTRec

TH1F* MuonAlignmentAnalyzer::hSAPTRec

private

Definition at line 132 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTRec_Barrel

TH1F* MuonAlignmentAnalyzer::hSAPTRec_Barrel

private

Definition at line 135 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTRec_Endcap

TH1F* MuonAlignmentAnalyzer::hSAPTRec_Endcap

private

Definition at line 138 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTres

TH1F* MuonAlignmentAnalyzer::hSAPTres

private

Definition at line 154 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTres_Barrel

TH1F* MuonAlignmentAnalyzer::hSAPTres_Barrel

private

Definition at line 158 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTres_Endcap

TH1F* MuonAlignmentAnalyzer::hSAPTres_Endcap

private

Definition at line 159 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTvsEta

TH2F* MuonAlignmentAnalyzer::hSAPTvsEta

private

Definition at line 143 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSAPTvsPhi

TH2F* MuonAlignmentAnalyzer::hSAPTvsPhi

private

Definition at line 144 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimInvM

TH1F* MuonAlignmentAnalyzer::hSimInvM

private

Definition at line 116 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimInvM_Barrel

TH1F* MuonAlignmentAnalyzer::hSimInvM_Barrel

private

Definition at line 120 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimInvM_Endcap

TH1F* MuonAlignmentAnalyzer::hSimInvM_Endcap

private

Definition at line 124 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimInvM_Overlap

TH1F* MuonAlignmentAnalyzer::hSimInvM_Overlap

private

Definition at line 129 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimNmuons

TH1F* MuonAlignmentAnalyzer::hSimNmuons

private

Definition at line 89 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimNmuons_Barrel

TH1F* MuonAlignmentAnalyzer::hSimNmuons_Barrel

private

Definition at line 92 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimNmuons_Endcap

TH1F* MuonAlignmentAnalyzer::hSimNmuons_Endcap

private

Definition at line 95 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPhivsEta

TH2F* MuonAlignmentAnalyzer::hSimPhivsEta

private

Definition at line 149 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPT

TH1F* MuonAlignmentAnalyzer::hSimPT

private

Definition at line 134 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPT_Barrel

TH1F* MuonAlignmentAnalyzer::hSimPT_Barrel

private

Definition at line 137 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPT_Endcap

TH1F* MuonAlignmentAnalyzer::hSimPT_Endcap

private

Definition at line 140 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPTvsEta

TH2F* MuonAlignmentAnalyzer::hSimPTvsEta

private

Definition at line 145 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

hSimPTvsPhi

TH2F* MuonAlignmentAnalyzer::hSimPTvsPhi

private

Definition at line 146 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and beginJob().

invMassRangeMax

double MuonAlignmentAnalyzer::invMassRangeMax

private

Definition at line 276 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and MuonAlignmentAnalyzer().

invMassRangeMin

double MuonAlignmentAnalyzer::invMassRangeMin

private

Definition at line 276 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and MuonAlignmentAnalyzer().

magFieldToken_

const edm::ESGetToken<MagneticField, IdealMagneticFieldRecord> MuonAlignmentAnalyzer::magFieldToken_

private

Definition at line 60 of file MuonAlignmentAnalyzer.h.

Referenced by analyze().

min1DTrackRecHitSize

unsigned int MuonAlignmentAnalyzer::min1DTrackRecHitSize

private

Definition at line 281 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

min4DTrackSegmentSize

unsigned int MuonAlignmentAnalyzer::min4DTrackSegmentSize

private

Definition at line 281 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

nbins

unsigned int MuonAlignmentAnalyzer::nbins

private

Definition at line 281 of file MuonAlignmentAnalyzer.h.

Referenced by python.rootplot.utilities.Hist::__init_TGraph(), python.rootplot.utilities.Hist::__len__(), python.rootplot.root2matplotlib.Hist::_prepare_xaxis(), python.rootplot.root2matplotlib.Hist::_prepare_yaxis(), analyze(), python.rootplot.utilities.Hist::av_xerr(), python.rootplot.utilities.Hist::av_yerr(), python.rootplot.utilities.Hist::delete_bin(), python.rootplot.utilities.Hist::divide(), MuonAlignmentAnalyzer(), python.rootplot.utilities.Hist::TGraph(), and python.rootplot.utilities.Hist::TH1F().

numberOfGBRecTracks

int MuonAlignmentAnalyzer::numberOfGBRecTracks

private

Definition at line 271 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), endJob(), and MuonAlignmentAnalyzer().

numberOfHits

int MuonAlignmentAnalyzer::numberOfHits

private

Definition at line 273 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), endJob(), and MuonAlignmentAnalyzer().

numberOfSARecTracks

int MuonAlignmentAnalyzer::numberOfSARecTracks

private

Definition at line 272 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), endJob(), and MuonAlignmentAnalyzer().

numberOfSimTracks

int MuonAlignmentAnalyzer::numberOfSimTracks

private

Definition at line 270 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), endJob(), and MuonAlignmentAnalyzer().

ptRangeMax

double MuonAlignmentAnalyzer::ptRangeMax

private

Definition at line 276 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and MuonAlignmentAnalyzer().

ptRangeMin

double MuonAlignmentAnalyzer::ptRangeMin

private

Definition at line 276 of file MuonAlignmentAnalyzer.h.

Referenced by beginJob(), and MuonAlignmentAnalyzer().

resLocalXRangeStation1

double MuonAlignmentAnalyzer::resLocalXRangeStation1

private

Definition at line 278 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalXRangeStation2

double MuonAlignmentAnalyzer::resLocalXRangeStation2

private

Definition at line 278 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalXRangeStation3

double MuonAlignmentAnalyzer::resLocalXRangeStation3

private

Definition at line 278 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalXRangeStation4

double MuonAlignmentAnalyzer::resLocalXRangeStation4

private

Definition at line 278 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalYRangeStation1

double MuonAlignmentAnalyzer::resLocalYRangeStation1

private

Definition at line 279 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalYRangeStation2

double MuonAlignmentAnalyzer::resLocalYRangeStation2

private

Definition at line 279 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalYRangeStation3

double MuonAlignmentAnalyzer::resLocalYRangeStation3

private

Definition at line 279 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resLocalYRangeStation4

double MuonAlignmentAnalyzer::resLocalYRangeStation4

private

Definition at line 279 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resPhiRange

double MuonAlignmentAnalyzer::resPhiRange

private

Definition at line 280 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

resThetaRange

double MuonAlignmentAnalyzer::resThetaRange

private

Definition at line 280 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

theDataType

std::string MuonAlignmentAnalyzer::theDataType

private

Definition at line 80 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), beginJob(), endJob(), and MuonAlignmentAnalyzer().

theGLBMuonTag

edm::InputTag MuonAlignmentAnalyzer::theGLBMuonTag

private

Definition at line 72 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

thePropagator

Propagator* MuonAlignmentAnalyzer::thePropagator

private

Definition at line 267 of file MuonAlignmentAnalyzer.h.

Referenced by analyze().

theRecHits4DTagCSC

edm::InputTag MuonAlignmentAnalyzer::theRecHits4DTagCSC

private

Definition at line 77 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

theRecHits4DTagDT

edm::InputTag MuonAlignmentAnalyzer::theRecHits4DTagDT

private

Definition at line 76 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

theSTAMuonTag

edm::InputTag MuonAlignmentAnalyzer::theSTAMuonTag

private

Definition at line 73 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and MuonAlignmentAnalyzer().

trackingGeometryToken_

const edm::ESGetToken<GlobalTrackingGeometry, GlobalTrackingGeometryRecord> MuonAlignmentAnalyzer::trackingGeometryToken_

private

Definition at line 61 of file MuonAlignmentAnalyzer.h.

Referenced by analyze().

unitsGlobalPhi

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsGlobalPhi

private

Definition at line 182 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsGlobalRPhi

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsGlobalRPhi

private

Definition at line 181 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsGlobalRZ

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsGlobalRZ

private

Definition at line 184 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsGlobalTheta

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsGlobalTheta

private

Definition at line 183 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsLocalPhi

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsLocalPhi

private

Definition at line 178 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsLocalTheta

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsLocalTheta

private

Definition at line 179 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsLocalX

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsLocalX

private

Definition at line 177 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().

unitsLocalY

std::vector<TH1F *> MuonAlignmentAnalyzer::unitsLocalY

private

Definition at line 180 of file MuonAlignmentAnalyzer.h.

Referenced by analyze(), and endJob().