#include <PVFitter.h>

Public Member Functions
void	compressStore ()
	reduce size of primary vertex cache by increasing quality limit More...

void	dumpTxtFile ()

void	FitPerBunchCrossing ()

reco::BeamSpot	getBeamSpot ()

std::map< int, reco::BeamSpot >	getBeamSpotMap ()

int *	getFitLSRange ()

int	getNPVs ()

const std::map< int, int > &	getNPVsperBX ()

std::vector< BeamSpotFitPVData >	getpvStore ()

time_t *	getRefTime ()

double	getWidthX ()

double	getWidthXerr ()

double	getWidthY ()

double	getWidthYerr ()

double	getWidthZ ()

double	getWidthZerr ()

void	initialize (const edm::ParameterSet &iConfig, edm::ConsumesCollector &iColl)

bool	IsFitPerBunchCrossing ()

	PVFitter ()

	PVFitter (const edm::ParameterSet &iConfig, edm::ConsumesCollector &&iColl)

	PVFitter (const edm::ParameterSet &iConfig, edm::ConsumesCollector &iColl)

double	pvQuality (const reco::Vertex &pv) const
	vertex quality measure More...

double	pvQuality (const BeamSpotFitPVData &pv) const
	vertex quality measure More...

void	readEvent (const edm::Event &iEvent)

void	resetAll ()

void	resetLSRange ()

void	resetRefTime ()

void	resizepvStore (unsigned int rmSize)

bool	runBXFitter ()

bool	runFitter ()

void	setFitLSRange (int ls0, int ls1)

void	setRefTime (std::time_t t0, std::time_t t1)

void	setTree (TTree *tree)

virtual	~PVFitter ()

Private Attributes
std::map< int, std::vector< BeamSpotFitPVData > >	bxMap_

bool	debug_

bool	do3DFit_

double	dynamicQualityCut_

double	errorScale_

std::ofstream	fasciiFile

reco::BeamSpot	fbeamspot

int	fbeginLumiOfFit

std::map< int, reco::BeamSpot >	fbspotMap

int	fendLumiOfFit

bool	fFitPerBunchCrossing

std::time_t	freftime [2]

TTree *	ftree_

double	fwidthX

double	fwidthXerr

double	fwidthY

double	fwidthYerr

double	fwidthZ

double	fwidthZerr

TH2F *	hPVx

TH2F *	hPVy

unsigned int	maxNrVertices_

double	maxVtxNormChi2_

double	maxVtxR_

double	maxVtxZ_

unsigned int	minNrVertices_

double	minSumPt_

double	minVtxNdf_

unsigned int	minVtxTracks_

double	minVtxWgt_

std::map< int, int >	npvsmap_

std::string	outputTxt_

std::vector< double >	pvQualities_

std::vector< BeamSpotFitPVData >	pvStore_

double	sigmaCut_

BeamSpotTreeData	theBeamSpotTreeData_

bool	useOnlyFirstPV_

edm::EDGetTokenT< reco::VertexCollection >	vertexToken_

Detailed Description

Definition at line 43 of file PVFitter.h.

Constructor & Destructor Documentation

PVFitter::PVFitter ( )

inline

Definition at line 45 of file PVFitter.h.

References iEvent, initialize(), and d0_phi_analyzer_cff::PVFitter.

45 {}

PVFitter::PVFitter	(	const edm::ParameterSet &	iConfig,
		edm::ConsumesCollector &&	iColl
	)

Definition at line 44 of file PVFitter.cc.

References initialize().

   : ftree_(nullptr)
 {
   initialize(iConfig, iColl);
 }

PVFitter::PVFitter	(	const edm::ParameterSet &	iConfig,
		edm::ConsumesCollector &	iColl
	)

Definition at line 51 of file PVFitter.cc.

References initialize().

     :ftree_(nullptr)
 {
   initialize(iConfig, iColl);
 }

PVFitter::~PVFitter ( )

virtual

Definition at line 92 of file PVFitter.cc.

                     {
 
 }

Member Function Documentation

void PVFitter::compressStore ( )

reduce size of primary vertex cache by increasing quality limit

Definition at line 479 of file PVFitter.cc.

References dynamicQualityCut_, mps_fire::i, pvQualities_, pvQuality(), and pvStore_.

Referenced by readEvent().

 {
   //
   // fill vertex qualities
   //
   pvQualities_.resize(pvStore_.size());
   for ( unsigned int i=0; i<pvStore_.size(); ++i )  pvQualities_[i] = pvQuality(pvStore_[i]);
   sort(pvQualities_.begin(),pvQualities_.end());
   //
   // Set new quality cut to median. This cut will be used to reduce the
   // number of vertices in the store and also apply to all new vertices
   // until the next reset
   //
   dynamicQualityCut_ = pvQualities_[pvQualities_.size()/2];
   //
   // remove all vertices failing the cut from the store
   //   (to be moved to a more efficient memory management!)
   //
   unsigned int iwrite(0);
   for ( unsigned int i=0; i<pvStore_.size(); ++i ) {
     if ( pvQuality(pvStore_[i])>dynamicQualityCut_ )  continue;
     if ( i!=iwrite )  pvStore_[iwrite] = pvStore_[i];
     ++iwrite;
   }
   pvStore_.resize(iwrite);
   edm::LogInfo("PVFitter") << "Reduced primary vertex store size to "
                            << pvStore_.size() << " ; new dynamic quality cut = "
                            << dynamicQualityCut_ << std::endl;
 
 }

void PVFitter::dumpTxtFile ( )

Definition at line 473 of file PVFitter.cc.

                           {
 
 }

void PVFitter::FitPerBunchCrossing ( )

inline

Definition at line 63 of file PVFitter.h.

63 { fFitPerBunchCrossing = true; }

PVFitter::fFitPerBunchCrossing

bool fFitPerBunchCrossing

Definition: PVFitter.h:140

reco::BeamSpot PVFitter::getBeamSpot ( )

inline

Definition at line 91 of file PVFitter.h.

Referenced by AlcaBeamMonitor::endLuminosityBlock(), and BeamFitter::runPVandTrkFitter().

91 { return fbeamspot; }

PVFitter::fbeamspot

reco::BeamSpot fbeamspot

Definition: PVFitter.h:138

std::map<int, reco::BeamSpot> PVFitter::getBeamSpotMap ( )

inline

Definition at line 92 of file PVFitter.h.

Referenced by BeamFitter::runPVandTrkFitter().

92 { return fbspotMap; }

PVFitter::fbspotMap

std::map< int, reco::BeamSpot > fbspotMap

Definition: PVFitter.h:139

int* PVFitter::getFitLSRange ( )

inline

Definition at line 94 of file PVFitter.h.

References tmp.

                        {
     int *tmp=new int[2];
     tmp[0] = fbeginLumiOfFit;
     tmp[1] = fendLumiOfFit;
     return tmp;
   }

int PVFitter::getNPVs ( )

inline

Definition at line 120 of file PVFitter.h.

120 { return pvStore_.size(); }

PVFitter::pvStore_

std::vector< BeamSpotFitPVData > pvStore_

Definition: PVFitter.h:178

const std::map<int, int>& PVFitter::getNPVsperBX ( )

inline

Definition at line 122 of file PVFitter.h.

References genParticles_cff::map, and findQualityFiles::size.

                                          {
     
     npvsmap_.clear();
 
     for ( std::map<int,std::vector<BeamSpotFitPVData> >::const_iterator pvStore = bxMap_.begin(); 
       pvStore!=bxMap_.end(); ++pvStore) {
 
       npvsmap_[ pvStore->first ] = (pvStore->second).size();
 
     }
     return npvsmap_;
   }

std::vector<BeamSpotFitPVData> PVFitter::getpvStore ( )

inline

Definition at line 61 of file PVFitter.h.

61 { return pvStore_; }

PVFitter::pvStore_

std::vector< BeamSpotFitPVData > pvStore_

Definition: PVFitter.h:178

time_t* PVFitter::getRefTime ( )

inline

Definition at line 101 of file PVFitter.h.

                      {
    time_t *tmptime=new time_t[2];
    tmptime[0]=freftime[0];
    tmptime[1]=freftime[1];
    return tmptime;
   }

double PVFitter::getWidthX ( )

inline

Definition at line 54 of file PVFitter.h.

54 { return fwidthX; }

PVFitter::fwidthX

double fwidthX

Definition: PVFitter.h:171

double PVFitter::getWidthXerr ( )

inline

Definition at line 57 of file PVFitter.h.

Referenced by BeamFitter::runPVandTrkFitter().

57 { return fwidthXerr; }

PVFitter::fwidthXerr

double fwidthXerr

Definition: PVFitter.h:174

double PVFitter::getWidthY ( )

inline

Definition at line 55 of file PVFitter.h.

55 { return fwidthY; }

PVFitter::fwidthY

double fwidthY

Definition: PVFitter.h:172

double PVFitter::getWidthYerr ( )

inline

Definition at line 58 of file PVFitter.h.

58 { return fwidthYerr; }

PVFitter::fwidthYerr

double fwidthYerr

Definition: PVFitter.h:175

double PVFitter::getWidthZ ( )

inline

Definition at line 56 of file PVFitter.h.

56 { return fwidthZ; }

PVFitter::fwidthZ

double fwidthZ

Definition: PVFitter.h:173

double PVFitter::getWidthZerr ( )

inline

Definition at line 59 of file PVFitter.h.

59 { return fwidthZerr; }

PVFitter::fwidthZerr

double fwidthZerr

Definition: PVFitter.h:176

void PVFitter::initialize	(	const edm::ParameterSet &	iConfig,
		edm::ConsumesCollector &	iColl
	)

Definition at line 58 of file PVFitter.cc.

References edm::ConsumesCollector::consumes(), debug_, do3DFit_, dynamicQualityCut_, errorScale_, fFitPerBunchCrossing, edm::ParameterSet::getParameter(), hPVx, hPVy, maxNrVertices_, maxVtxNormChi2_, maxVtxR_, maxVtxZ_, minNrVertices_, minSumPt_, minVtxNdf_, minVtxTracks_, minVtxWgt_, sigmaCut_, useOnlyFirstPV_, and vertexToken_.

Referenced by PVFitter().

 {
   //In order to make fitting ROOT histograms thread safe
   // one must call this undocumented function
   TMinuitMinimizer::UseStaticMinuit(false);
   debug_             = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<bool>("Debug");
   vertexToken_       = iColl.consumes<reco::VertexCollection>(
       iConfig.getParameter<edm::ParameterSet>("PVFitter")
       .getUntrackedParameter<edm::InputTag>("VertexCollection", edm::InputTag("offlinePrimaryVertices")));
   do3DFit_           = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<bool>("Apply3DFit");
   //writeTxt_          = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<bool>("WriteAscii");
   //outputTxt_         = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<std::string>("AsciiFileName");
   maxNrVertices_     = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<unsigned int>("maxNrStoredVertices");
   minNrVertices_     = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<unsigned int>("minNrVerticesForFit");
   minVtxNdf_         = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("minVertexNdf");
   maxVtxNormChi2_    = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("maxVertexNormChi2");
   minVtxTracks_      = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<unsigned int>("minVertexNTracks");
   minVtxWgt_         = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("minVertexMeanWeight");
   maxVtxR_           = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("maxVertexR");
   maxVtxZ_           = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("maxVertexZ");
   errorScale_        = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("errorScale");
   sigmaCut_          = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("nSigmaCut");
   fFitPerBunchCrossing=iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<bool>("FitPerBunchCrossing");
   useOnlyFirstPV_    = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<bool>("useOnlyFirstPV");
   minSumPt_          = iConfig.getParameter<edm::ParameterSet>("PVFitter").getUntrackedParameter<double>("minSumPt");
   
   // preset quality cut to "infinite"
   dynamicQualityCut_ = 1.e30;
 
   hPVx = new TH2F("hPVx","PVx vs PVz distribution",200,-maxVtxR_, maxVtxR_, 200, -maxVtxZ_, maxVtxZ_);
   hPVy = new TH2F("hPVy","PVy vs PVz distribution",200,-maxVtxR_, maxVtxR_, 200, -maxVtxZ_, maxVtxZ_);
 }

bool PVFitter::IsFitPerBunchCrossing ( )

inline

Definition at line 93 of file PVFitter.h.

Referenced by BeamFitter::dumpTxtFile(), and BeamFitter::runPVandTrkFitter().

93 { return fFitPerBunchCrossing; }

PVFitter::fFitPerBunchCrossing

bool fFitPerBunchCrossing

Definition: PVFitter.h:140

double PVFitter::pvQuality ( const reco::Vertex & pv ) const

vertex quality measure

Definition at line 511 of file PVFitter.cc.

References reco::Vertex::covariance().

Referenced by compressStore(), and readEvent().

 {
   //
   // determinant of the transverse part of the PV covariance matrix
   //
   return
     pv.covariance(0,0)*pv.covariance(1,1)-
     pv.covariance(0,1)*pv.covariance(0,1);
 }

double PVFitter::pvQuality ( const BeamSpotFitPVData & pv ) const

vertex quality measure

Definition at line 522 of file PVFitter.cc.

References BeamSpotFitPVData::posCorr, and BeamSpotFitPVData::posError.

 {
   //
   // determinant of the transverse part of the PV covariance matrix
   //
   double ex = pv.posError[0];
   double ey = pv.posError[1];
   return ex*ex*ey*ey*(1-pv.posCorr[0]*pv.posCorr[0]);
 }

void PVFitter::readEvent ( const edm::Event & iEvent )

Definition at line 97 of file PVFitter.cc.

References BeamSpotFitPVData::bunchCrossing, BeamSpotTreeData::bunchCrossing(), edm::EventBase::bunchCrossing(), bxMap_, compressStore(), dynamicQualityCut_, fFitPerBunchCrossing, ftree_, edm::Event::getByToken(), hPVx, hPVy, edm::EventBase::id(), BeamSpotTreeData::lumi(), edm::EventBase::luminosityBlock(), maxNrVertices_, minSumPt_, minVtxNdf_, minVtxTracks_, minVtxWgt_, BeamSpotFitPVData::posCorr, BeamSpotFitPVData::posError, BeamSpotFitPVData::position, EnergyCorrector::pt, MetAnalyzer::pv(), BeamSpotTreeData::pvData(), pvQuality(), pvStore_, BeamSpotTreeData::run(), edm::EventID::run(), TtFullHadEvtBuilder_cfi::sumPt, theBeamSpotTreeData_, useOnlyFirstPV_, and vertexToken_.

Referenced by AlcaBeamMonitor::analyze(), and BeamFitter::readEvent().

 {
 
   //------ Primary Vertices
   edm::Handle< reco::VertexCollection > PVCollection;
   bool hasPVs = false;
 
   if ( iEvent.getByToken(vertexToken_, PVCollection ) ) {
       hasPVs = true;
   }
   //------
 
   if ( hasPVs ) {
 
       for (reco::VertexCollection::const_iterator pv = PVCollection->begin(); pv != PVCollection->end(); ++pv ) {
           if (useOnlyFirstPV_){
             if (pv != PVCollection->begin()) break;
           }
 
           //--- vertex selection
           if ( pv->isFake() || pv->tracksSize()==0 )  continue;
           if ( pv->ndof() < minVtxNdf_ || (pv->ndof()+3.)/pv->tracksSize()<2*minVtxWgt_ )  continue;
           //---
 
           if (pv->tracksSize() < minVtxTracks_ ) continue;
 
           const auto& testTrack = pv->trackRefAt(0);
           if(testTrack.isNull() || !testTrack.isAvailable())
           {
               edm::LogInfo("") << "Track collection not found. Skipping cut on sumPt.";
           }
           else
           {
               double sumPt=0;
               for(auto iTrack = pv->tracks_begin(); iTrack != pv->tracks_end(); ++iTrack)
               {
                   const auto pt = (*iTrack)->pt();
                   sumPt += pt;
               }
               if (sumPt < minSumPt_) continue;
           }
 
           hPVx->Fill( pv->x(), pv->z() );
           hPVy->Fill( pv->y(), pv->z() );
 
           //
           // 3D fit section
           //
           // apply additional quality cut
           if ( pvQuality(*pv)>dynamicQualityCut_ )  continue;
           // if store exceeds max. size: reduce size and apply new quality cut
           if ( pvStore_.size()>=maxNrVertices_ ) {
              compressStore();
              if ( pvQuality(*pv)>dynamicQualityCut_ )  continue;
           }
           //
           // copy PV to store
           //
           int bx = iEvent.bunchCrossing();
           BeamSpotFitPVData pvData;
           pvData.bunchCrossing = bx;
           pvData.position[0] = pv->x();
           pvData.position[1] = pv->y();
           pvData.position[2] = pv->z();
           pvData.posError[0] = pv->xError();
           pvData.posError[1] = pv->yError();
           pvData.posError[2] = pv->zError();
           pvData.posCorr[0] = pv->covariance(0,1)/pv->xError()/pv->yError();
           pvData.posCorr[1] = pv->covariance(0,2)/pv->xError()/pv->zError();
           pvData.posCorr[2] = pv->covariance(1,2)/pv->yError()/pv->zError();
           pvStore_.push_back(pvData);
 
       if(ftree_ != nullptr){
         theBeamSpotTreeData_.run(iEvent.id().run());
         theBeamSpotTreeData_.lumi(iEvent.luminosityBlock());
         theBeamSpotTreeData_.bunchCrossing(bx);
         theBeamSpotTreeData_.pvData(pvData);
         ftree_->Fill();
       }
 
       if (fFitPerBunchCrossing) bxMap_[bx].push_back(pvData);
 
       }
 
   }
 
 }

void PVFitter::resetAll ( )

inline

Definition at line 80 of file PVFitter.h.

References align::BeamSpot.

Referenced by BeamFitter::BeamFitter(), and AlcaBeamMonitor::endLuminosityBlock().

                   {
     resetLSRange();
     resetRefTime();
     pvStore_.clear();
     bxMap_.clear();
     dynamicQualityCut_ = 1.e30;
     hPVx->Reset();
     hPVy->Reset();
     fbeamspot = reco::BeamSpot();
     fbspotMap.clear();
   };

void PVFitter::resetLSRange ( )

inline

Definition at line 66 of file PVFitter.h.

66 { fbeginLumiOfFit=fendLumiOfFit=-1; }

PVFitter::fbeginLumiOfFit

int fbeginLumiOfFit

Definition: PVFitter.h:169

PVFitter::fendLumiOfFit

int fendLumiOfFit

Definition: PVFitter.h:170

void PVFitter::resetRefTime ( )

inline

Definition at line 67 of file PVFitter.h.

67 { freftime[0] = freftime[1] = 0; }

PVFitter::freftime

std::time_t freftime[2]

Definition: PVFitter.h:162

void PVFitter::resizepvStore ( unsigned int rmSize )

inline

Definition at line 109 of file PVFitter.h.

References MetAnalyzer::pv().

                                          {
   pvStore_.erase(pvStore_.begin(), pvStore_.begin()+rmSize);
   }

bool PVFitter::runBXFitter ( )

Definition at line 190 of file PVFitter.cc.

References align::BeamSpot, bxMap_, errorScale_, fbeamspot, fbspotMap, fcn(), fwidthX, fwidthXerr, fwidthY, fwidthYerr, fwidthZ, fwidthZerr, genParticles_cff::map, makeMuonMisalignmentScenario::matrix, minNrVertices_, funct::pow(), reco::BeamSpot::setBeamWidthX(), reco::BeamSpot::setBeamWidthY(), FcnBeamSpotFitPV::setLimits(), reco::BeamSpot::setType(), sigmaCut_, findQualityFiles::size, and reco::BeamSpot::Tracker.

Referenced by BeamFitter::runPVandTrkFitter().

                            {
 
   using namespace ROOT::Minuit2;
   edm::LogInfo("PVFitter") << " Number of bunch crossings: " << bxMap_.size() << std::endl;
 
   bool fit_ok = true;
 
   for ( std::map<int,std::vector<BeamSpotFitPVData> >::const_iterator pvStore = bxMap_.begin();
     pvStore!=bxMap_.end(); ++pvStore) {
 
     // first set null beam spot in case
     // fit fails
     fbspotMap[pvStore->first] = reco::BeamSpot();
 
     edm::LogInfo("PVFitter") << " Number of PVs collected for PVFitter: " << (pvStore->second).size() << " in bx: " << pvStore->first << std::endl;
 
     if ( (pvStore->second).size() <= minNrVertices_ ) {
         edm::LogWarning("PVFitter") << " not enough PVs, continue" << std::endl;
     fit_ok = false;
       continue;
     }
 
     edm::LogInfo("PVFitter") << "Calculating beam spot with PVs ..." << std::endl;
 
     //
     // LL function and fitter
     //
     FcnBeamSpotFitPV* fcn = new FcnBeamSpotFitPV(pvStore->second);
     //
     // fit parameters: positions, widths, x-y correlations, tilts in xz and yz
     //
     MnUserParameters upar;
     upar.Add("x"     , 0.   , 0.02  , -10., 10.);  // 0
     upar.Add("y"     , 0.   , 0.02  , -10., 10.);  // 1
     upar.Add("z"     , 0.   , 0.20  , -30., 30.);  // 2
     upar.Add("ex"    , 0.015, 0.01  , 0.  , 10.);  // 3
     upar.Add("corrxy", 0.   , 0.02  , -1. , 1. );  // 4
     upar.Add("ey"    , 0.015, 0.01  , 0.  , 10.);  // 5
     upar.Add("dxdz"  , 0.   , 0.0002, -0.1, 0.1);  // 6
     upar.Add("dydz"  , 0.   , 0.0002, -0.1, 0.1);  // 7
     upar.Add("ez"    , 1.   , 0.1   , 0.  , 30.);  // 8
     upar.Add("scale", errorScale_   , errorScale_/10.,
                       errorScale_/2., errorScale_*2.);      // 9
     MnMigrad migrad(*fcn, upar);
 
     //
     // first iteration without correlations
     //
     upar.Fix(4);
     upar.Fix(6);
     upar.Fix(7);
     upar.Fix(9);
     FunctionMinimum ierr = migrad(0,1.);
     if ( !ierr.IsValid() ) {
         edm::LogInfo("PVFitter") << "3D beam spot fit failed in 1st iteration" << std::endl;
     fit_ok = false;
       continue;
     }
     //
     // refit with harder selection on vertices
     //
     fcn->setLimits(upar.Value(0)-sigmaCut_*upar.Value(3),
            upar.Value(0)+sigmaCut_*upar.Value(3),
            upar.Value(1)-sigmaCut_*upar.Value(5),
            upar.Value(1)+sigmaCut_*upar.Value(5),
            upar.Value(2)-sigmaCut_*upar.Value(8),
            upar.Value(2)+sigmaCut_*upar.Value(8));
     ierr = migrad(0,1.);
     if ( !ierr.IsValid() ) {
       edm::LogInfo("PVFitter") << "3D beam spot fit failed in 2nd iteration" << std::endl;
       fit_ok = false;
       continue;
     }
     //
     // refit with correlations
     //
     upar.Release(4);
     upar.Release(6);
     upar.Release(7);
     ierr = migrad(0,1.);
     if ( !ierr.IsValid() ) {
         edm::LogInfo("PVFitter") << "3D beam spot fit failed in 3rd iteration" << std::endl;
     fit_ok = false;
       continue;
     }
 
     fwidthX = upar.Value(3);
     fwidthY = upar.Value(5);
     fwidthZ = upar.Value(8);
     fwidthXerr = upar.Error(3);
     fwidthYerr = upar.Error(5);
     fwidthZerr = upar.Error(8);
 
     reco::BeamSpot::CovarianceMatrix matrix;
     // need to get the full cov matrix
     matrix(0,0) = pow( upar.Error(0), 2);
     matrix(1,1) = pow( upar.Error(1), 2);
     matrix(2,2) = pow( upar.Error(2), 2);
     matrix(3,3) = fwidthZerr * fwidthZerr;
     matrix(4,4) = pow( upar.Error(6), 2);
     matrix(5,5) = pow( upar.Error(7), 2);
     matrix(6,6) = fwidthXerr * fwidthXerr;
 
     fbeamspot = reco::BeamSpot( reco::BeamSpot::Point(upar.Value(0),
                               upar.Value(1),
                               upar.Value(2) ),
                 fwidthZ,
                 upar.Value(6), upar.Value(7),
                 fwidthX,
                 matrix );
     fbeamspot.setBeamWidthX( fwidthX );
     fbeamspot.setBeamWidthY( fwidthY );
     fbeamspot.setType( reco::BeamSpot::Tracker );
 
     fbspotMap[pvStore->first] = fbeamspot;
     edm::LogInfo("PVFitter") << "3D PV fit done for this bunch crossing."<<std::endl;
     //delete fcn;
     fit_ok = fit_ok & true;
   }
 
   return fit_ok;
 }

bool PVFitter::runFitter ( )

Definition at line 314 of file PVFitter.cc.

References align::BeamSpot, do3DFit_, benchmark_cfg::errors, errorScale_, fftjetvertexadder_cfi::errX, fftjetvertexadder_cfi::errY, fftjetvertexadder_cfi::errZ, fbeamspot, fcn(), fwidthX, fwidthXerr, fwidthY, fwidthYerr, fwidthZ, fwidthZerr, hPVx, hPVy, edm::isNotFinite(), makeMuonMisalignmentScenario::matrix, minNrVertices_, funct::pow(), pvStore_, mps_update::results, reco::BeamSpot::setBeamWidthX(), reco::BeamSpot::setBeamWidthY(), reco::BeamSpot::setType(), sigmaCut_, and reco::BeamSpot::Tracker.

Referenced by AlcaBeamMonitor::endLuminosityBlock(), and BeamFitter::runPVandTrkFitter().

                          {
 
     using namespace ROOT::Minuit2;
     edm::LogInfo("PVFitter") << " Number of PVs collected for PVFitter: " << pvStore_.size() << std::endl;
 
     if ( pvStore_.size() <= minNrVertices_ ) return false;
 
     TH1F *h1PVx = (TH1F*) hPVx->ProjectionX("h1PVx", 0, -1, "e");
     TH1F *h1PVy = (TH1F*) hPVy->ProjectionX("h1PVy", 0, -1, "e");
     TH1F *h1PVz = (TH1F*) hPVx->ProjectionY("h1PVz", 0, -1, "e");
 
     //Use our own copy for thread safety
     // also do not add to global list of functions
     TF1 gausx("localGausX","gaus",0.,1.,TF1::EAddToList::kNo);
     TF1 gausy("localGausY","gaus",0.,1.,TF1::EAddToList::kNo);
     TF1 gausz("localGausZ","gaus",0.,1.,TF1::EAddToList::kNo);
 
     h1PVx->Fit(&gausx,"QLMN0");
     h1PVy->Fit(&gausy,"QLMN0");
     h1PVz->Fit(&gausz,"QLMN0");
 
 
     fwidthX     = gausx.GetParameter(2);
     fwidthY     = gausy.GetParameter(2);
     fwidthZ     = gausz.GetParameter(2);
     fwidthXerr  = gausx.GetParError(2);
     fwidthYerr  = gausy.GetParError(2);
     fwidthZerr  = gausz.GetParError(2);
     
     double estX = gausx.GetParameter(1);
     double estY = gausy.GetParameter(1); 
     double estZ = gausz.GetParameter(1);
     double errX = fwidthX*3.;
     double errY = fwidthY*3.; 
     double errZ = fwidthZ*3.;
 
     if ( ! do3DFit_ ) {
 
       reco::BeamSpot::CovarianceMatrix matrix;
       matrix(2,2) = gausz.GetParError(1) * gausz.GetParError(1);
       matrix(3,3) = fwidthZerr * fwidthZerr;
       matrix(6,6) = fwidthXerr * fwidthXerr;
 
       fbeamspot = reco::BeamSpot( reco::BeamSpot::Point(gausx.GetParameter(1),
                                                         gausy.GetParameter(1),
                                                         gausz.GetParameter(1) ),
                                   fwidthZ,
                                   0., 0.,
                                   fwidthX,
                                   matrix );
       fbeamspot.setBeamWidthX( fwidthX );
       fbeamspot.setBeamWidthY( fwidthY );
       fbeamspot.setType(reco::BeamSpot::Tracker);
 
     }
     else { // do 3D fit
       //
       // LL function and fitter
       //
       FcnBeamSpotFitPV* fcn = new FcnBeamSpotFitPV(pvStore_);
       //
       // fit parameters: positions, widths, x-y correlations, tilts in xz and yz
       //
       MnUserParameters upar;
       upar.Add("x"     , estX       , errX       , -10.     , 10.       ); // 0
       upar.Add("y"     , estY       , errY       , -10.     , 10.       ); // 1
       upar.Add("z"     , estZ       , errZ       , -30.     , 30.       ); // 2
       upar.Add("ex"    , 0.015      , 0.01       , 0.       , 10.       ); // 3
       upar.Add("corrxy", 0.         , 0.02       , -1.      , 1.        ); // 4
       upar.Add("ey"    , 0.015      , 0.01       , 0.       , 10.       ); // 5
       upar.Add("dxdz"  , 0.         , 0.0002     , -0.1     , 0.1       ); // 6
       upar.Add("dydz"  , 0.         , 0.0002     , -0.1     , 0.1       ); // 7
       upar.Add("ez"    , 1.         , 0.1        , 0.       , 30.       ); // 8
       upar.Add("scale" , errorScale_, errorScale_/10.,errorScale_/2., errorScale_*2.); // 9  
       MnMigrad migrad(*fcn, upar);
       //
       // first iteration without correlations
       //
       migrad.Fix(4);
       migrad.Fix(6);
       migrad.Fix(7);
       migrad.Fix(9);
       FunctionMinimum ierr = migrad(0,1.);
       if ( !ierr.IsValid() ) {
           edm::LogWarning("PVFitter") << "3D beam spot fit failed in 1st iteration" << std::endl;
           return false;
       }
       //
       // refit with harder selection on vertices
       //
 
       vector<double> results ;
       vector<double> errors  ;
       results = ierr.UserParameters().Params() ;                           \
       errors  = ierr.UserParameters().Errors() ;                           \
 
       
       fcn->setLimits(results[0]-sigmaCut_*results[3],
                      results[0]+sigmaCut_*results[3],
                      results[1]-sigmaCut_*results[5],
                      results[1]+sigmaCut_*results[5],
                      results[2]-sigmaCut_*results[8],
                      results[2]+sigmaCut_*results[8]);
       ierr = migrad(0,1.);
       if ( !ierr.IsValid() ) {
           edm::LogWarning("PVFitter") << "3D beam spot fit failed in 2nd iteration" << std::endl;
           return false;
       }
       //
       // refit with correlations
       //
       migrad.Release(4);
       migrad.Release(6);
       migrad.Release(7);
       ierr = migrad(0,1.);
       if ( !ierr.IsValid() ) {
           edm::LogWarning("PVFitter") << "3D beam spot fit failed in 3rd iteration" << std::endl;
           return false;
       }
 
       results = ierr.UserParameters().Params() ;                           \
       errors  = ierr.UserParameters().Errors() ;                           \
 
       fwidthX = results[3];
       fwidthY = results[5];
       fwidthZ = results[8];
       fwidthXerr = errors[3];
       fwidthYerr = errors[5];
       fwidthZerr = errors[8];
 
       // check errors on widths and sigmaZ for nan
       if ( edm::isNotFinite(fwidthXerr) || edm::isNotFinite(fwidthYerr) || edm::isNotFinite(fwidthZerr) ) {
           edm::LogWarning("PVFitter") << "3D beam spot fit returns nan in 3rd iteration" << std::endl;
           return false;
       }
 
       reco::BeamSpot::CovarianceMatrix matrix;
       // need to get the full cov matrix
       matrix(0,0) = pow( errors[0], 2);
       matrix(1,1) = pow( errors[1], 2);
       matrix(2,2) = pow( errors[2], 2);
       matrix(3,3) = fwidthZerr * fwidthZerr;
       matrix(6,6) = fwidthXerr * fwidthXerr;
 
       fbeamspot = reco::BeamSpot( reco::BeamSpot::Point(results[0],
                                                         results[1],
                                                         results[2] ),
                                   fwidthZ,
                                   results[6], results[7],
                                   fwidthX,
                                   matrix );
       fbeamspot.setBeamWidthX( fwidthX );
       fbeamspot.setBeamWidthY( fwidthY );
       fbeamspot.setType(reco::BeamSpot::Tracker); 
     }
 
     return true;
 }

void PVFitter::setFitLSRange	(	int	ls0,
		int	ls1
	)

inline

Definition at line 73 of file PVFitter.h.

                                        {
     fbeginLumiOfFit = ls0;
     fendLumiOfFit = ls1;
   }

void PVFitter::setRefTime	(	std::time_t	t0,
		std::time_t	t1
	)

inline

Definition at line 69 of file PVFitter.h.

References cscNeutronWriter_cfi::t0.

                                               {
     freftime[0] = t0;
     freftime[1] = t1;
   }

void PVFitter::setTree ( TTree * tree )

Definition at line 185 of file PVFitter.cc.

References BeamSpotTreeData::branch(), ftree_, theBeamSpotTreeData_, and compare::tree.

Referenced by BeamFitter::BeamFitter().

                                  {
   ftree_ = tree;
   theBeamSpotTreeData_.branch(ftree_);
 }

Member Data Documentation

std::map< int, std::vector<BeamSpotFitPVData> > PVFitter::bxMap_

private

Definition at line 179 of file PVFitter.h.

Referenced by readEvent(), and runBXFitter().

bool PVFitter::debug_

private

Definition at line 145 of file PVFitter.h.

Referenced by initialize().

bool PVFitter::do3DFit_

private

Definition at line 146 of file PVFitter.h.

Referenced by initialize(), and runFitter().

double PVFitter::dynamicQualityCut_

private

Definition at line 180 of file PVFitter.h.

Referenced by compressStore(), initialize(), and readEvent().

double PVFitter::errorScale_

private

Definition at line 158 of file PVFitter.h.

Referenced by initialize(), runBXFitter(), and runFitter().

std::ofstream PVFitter::fasciiFile

private

Definition at line 143 of file PVFitter.h.

reco::BeamSpot PVFitter::fbeamspot

private

Definition at line 138 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

int PVFitter::fbeginLumiOfFit

private

Definition at line 169 of file PVFitter.h.

std::map<int,reco::BeamSpot> PVFitter::fbspotMap

private

Definition at line 139 of file PVFitter.h.

Referenced by runBXFitter().

int PVFitter::fendLumiOfFit

private

Definition at line 170 of file PVFitter.h.

bool PVFitter::fFitPerBunchCrossing

private

Definition at line 140 of file PVFitter.h.

Referenced by initialize(), and readEvent().

std::time_t PVFitter::freftime[2]

private

Definition at line 162 of file PVFitter.h.

TTree* PVFitter::ftree_

private

Definition at line 166 of file PVFitter.h.

Referenced by readEvent(), and setTree().

double PVFitter::fwidthX

private

Definition at line 171 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

double PVFitter::fwidthXerr

private

Definition at line 174 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

double PVFitter::fwidthY

private

Definition at line 172 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

double PVFitter::fwidthYerr

private

Definition at line 175 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

double PVFitter::fwidthZ

private

Definition at line 173 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

double PVFitter::fwidthZerr

private

Definition at line 176 of file PVFitter.h.

Referenced by runBXFitter(), and runFitter().

TH2F* PVFitter::hPVx

private

Definition at line 164 of file PVFitter.h.

Referenced by initialize(), readEvent(), and runFitter().

TH2F* PVFitter::hPVy

private

Definition at line 164 of file PVFitter.h.

Referenced by initialize(), readEvent(), and runFitter().

unsigned int PVFitter::maxNrVertices_

private

Definition at line 150 of file PVFitter.h.

Referenced by initialize(), and readEvent().

double PVFitter::maxVtxNormChi2_

private

Definition at line 153 of file PVFitter.h.

Referenced by initialize().

double PVFitter::maxVtxR_

private

Definition at line 156 of file PVFitter.h.

Referenced by initialize().

double PVFitter::maxVtxZ_

private

Definition at line 157 of file PVFitter.h.

Referenced by initialize().

unsigned int PVFitter::minNrVertices_

private

Definition at line 151 of file PVFitter.h.

Referenced by initialize(), runBXFitter(), and runFitter().

double PVFitter::minSumPt_

private

Definition at line 160 of file PVFitter.h.

Referenced by initialize(), and readEvent().

double PVFitter::minVtxNdf_

private

Definition at line 152 of file PVFitter.h.

Referenced by initialize(), and readEvent().

unsigned int PVFitter::minVtxTracks_

private

Definition at line 154 of file PVFitter.h.

Referenced by initialize(), and readEvent().

double PVFitter::minVtxWgt_

private

Definition at line 155 of file PVFitter.h.

Referenced by initialize(), and readEvent().

std::map<int, int> PVFitter::npvsmap_

private

Definition at line 137 of file PVFitter.h.

std::string PVFitter::outputTxt_

private

Definition at line 148 of file PVFitter.h.

std::vector<double> PVFitter::pvQualities_

private

Definition at line 181 of file PVFitter.h.

Referenced by compressStore().

std::vector<BeamSpotFitPVData> PVFitter::pvStore_

private

Definition at line 178 of file PVFitter.h.

Referenced by compressStore(), readEvent(), and runFitter().

double PVFitter::sigmaCut_

private

Definition at line 159 of file PVFitter.h.

Referenced by initialize(), runBXFitter(), and runFitter().

BeamSpotTreeData PVFitter::theBeamSpotTreeData_

private

Definition at line 183 of file PVFitter.h.

Referenced by readEvent(), and setTree().

bool PVFitter::useOnlyFirstPV_

private

Definition at line 141 of file PVFitter.h.

Referenced by initialize(), and readEvent().

edm::EDGetTokenT<reco::VertexCollection> PVFitter::vertexToken_

private

Definition at line 147 of file PVFitter.h.

Referenced by initialize(), and readEvent().

Public Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation