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Public Member Functions | Private Types | Private Attributes

SiStripCalibLorentzAngle Class Reference

#include <SiStripCalibLorentzAngle.h>

Inheritance diagram for SiStripCalibLorentzAngle:
ConditionDBWriter< SiStripLorentzAngle > edm::EDAnalyzer

List of all members.

Public Member Functions

void algoBeginJob (const edm::EventSetup &)
SiStripLorentzAnglegetNewObject ()
 SiStripCalibLorentzAngle (const edm::ParameterSet &conf)
virtual ~SiStripCalibLorentzAngle ()

Private Types

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

Private Attributes

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

Detailed Description

Definition at line 36 of file SiStripCalibLorentzAngle.h.


Member Typedef Documentation

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

Definition at line 55 of file SiStripCalibLorentzAngle.h.

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

Definition at line 57 of file SiStripCalibLorentzAngle.h.

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

Definition at line 59 of file SiStripCalibLorentzAngle.h.


Constructor & Destructor Documentation

SiStripCalibLorentzAngle::SiStripCalibLorentzAngle ( const edm::ParameterSet conf) [explicit]
SiStripCalibLorentzAngle::~SiStripCalibLorentzAngle ( ) [virtual]

Definition at line 757 of file SiStripCalibLorentzAngle.cc.

References hFile.

                                                   {
 delete hFile;
}

Member Function Documentation

void SiStripCalibLorentzAngle::algoBeginJob ( const edm::EventSetup c) [virtual]

Reimplemented from ConditionDBWriter< SiStripLorentzAngle >.

Definition at line 24 of file SiStripCalibLorentzAngle.cc.

References badFit, BoundSurface::bounds(), CalibByMC, conf_, dbe_, cond::rpcobgas::detid, detid_la, estracker, PV3DBase< T, PVType, FrameType >::eta(), extract(), FirstIT_GoodFit_Histos, fitfunc, fitfunc2IT, FitFunction, FitFunction2IT, edm::EventSetup::get(), geta, DQMStore::getAllContents(), SiStripHistoId::getComponentId(), edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), globalX, globalY, globalZ, goodFit, goodFit1IT, gphi, gposition, gR, gz, hFile, interpolateCardsSimple::histo, histoEntries, histolist, errorMatrix2Lands_multiChannel::id, TrackerGeometry::idToDetUnit(), TIBDetId::layer(), TOBDetId::layer(), Layer, LayerDB, StripTopology::localPitch(), LorentzAngle_Plots, PV3DBase< T, PVType, FrameType >::mag(), magfield_, mean_TIB1, mean_TIB2, mean_TIB3, mean_TIB4, mean_TOB1, mean_TOB2, mean_TOB3, mean_TOB4, mean_TOB5, mean_TOB6, meanMobility_TIB, meanMobility_TOB, ModuleTree, MonoStereo, muH, MuH, MuH_vs_Eta, MuH_vs_Phi, mergeVDriftHistosByStation::name, DQMStore::open(), cppFunctionSkipper::operator, AlCaHLTBitMon_ParallelJobs::p, PV3DBase< T, PVType, FrameType >::phi(), GloballyPositioned< T >::position(), funct::pow(), Profiles, Rootple, SecondIT_BadFit_Histos, SecondIT_GoodFit_Histos, GeomDet::specificSurface(), mathSSE::sqrt(), StripSubdetector::stereo(), DetId::subdetId(), GeomDet::surface(), TH1Ds, TH2Ds, theBfield, Bounds::thickness(), StripSubdetector::TIB, TIB, TIB_1IT_GoodFit, TIB_2IT_BadFit, TIB_2IT_GoodFit, TIB_Eta, TIB_graph, TIB_MuH, TIB_Phi, TOB, StripSubdetector::TOB, TOB_1IT_GoodFit, TOB_2IT_BadFit, TOB_2IT_GoodFit, TOB_Eta, TOB_graph, TOB_MuH, TOB_Phi, toLocal(), GeomDetUnit::topology(), tracker, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

                                                                 {

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

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

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

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

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

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

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

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

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

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

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

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

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

Implements ConditionDBWriter< SiStripLorentzAngle >.

Definition at line 764 of file SiStripCalibLorentzAngle.cc.

References detid_la, estracker, hallMobility, TIBDetId::layer(), TOBDetId::layer(), LayerDB, mean_TIB1, mean_TIB2, mean_TIB3, mean_TIB4, mean_TOB1, mean_TOB2, mean_TOB3, mean_TOB4, mean_TOB5, mean_TOB6, meanMobility_TIB, meanMobility_TOB, SiStripLorentzAngle::putLorentzAngle(), TECDetId::ringNumber(), redigi_cff::SiStripLorentzAngle, StripSubdetector::TEC, StripSubdetector::TIB, StripSubdetector::TID, and StripSubdetector::TOB.

                                                           {

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

Member Data Documentation

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 73 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 84 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

std::map< uint32_t, float> SiStripCalibLorentzAngle::detid_la [private]

Definition at line 83 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 50 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 63 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 63 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 63 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 63 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 67 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 71 of file SiStripCalibLorentzAngle.h.

Referenced by getNewObject().

Definition at line 78 of file SiStripCalibLorentzAngle.h.

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

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 61 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 73 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 51 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 69 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 71 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 71 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob(), and getNewObject().

Definition at line 77 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH_vs_Eta [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::MuH_vs_Phi [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 56 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::Rootple [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 58 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 60 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 65 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_Eta [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TGraphErrors* SiStripCalibLorentzAngle::TIB_graph [private]

Definition at line 75 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_MuH [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TIB_Phi [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 66 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 81 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_Eta [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TGraphErrors * SiStripCalibLorentzAngle::TOB_graph [private]

Definition at line 75 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_MuH [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

TDirectory * SiStripCalibLorentzAngle::TOB_Phi [private]

Definition at line 80 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().

Definition at line 53 of file SiStripCalibLorentzAngle.h.

Referenced by algoBeginJob().