#include <HcalBeamMonitor.h>

Inheritance diagram for HcalBeamMonitor:

Public Member Functions
void	analyze (const edm::Event &e, const edm::EventSetup &c)

void	beginLuminosityBlock (const edm::LuminosityBlock &lumiSeg, const edm::EventSetup &c)

void	beginRun (const edm::Run &run, const edm::EventSetup &c)

void	cleanup ()

void	endLuminosityBlock (const edm::LuminosityBlock &lumiSeg, const edm::EventSetup &c)

	HcalBeamMonitor (const edm::ParameterSet &ps)

void	processEvent (const HBHERecHitCollection &hbHits, const HORecHitCollection &hoHits, const HFRecHitCollection &hfHits, const HFDigiCollection &hf, int bunchCrossing)

void	reset ()

void	setup ()

	~HcalBeamMonitor ()

Public Member Functions inherited from HcalBaseDQMonitor
	HcalBaseDQMonitor (const edm::ParameterSet &ps)

	HcalBaseDQMonitor ()

virtual	~HcalBaseDQMonitor ()

Public Member Functions inherited from edm::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

	EDAnalyzer ()

ModuleDescription const &	moduleDescription () const

std::string	workerType () const

virtual	~EDAnalyzer ()

Public Member Functions inherited from edm::EDConsumerBase
	EDConsumerBase ()

ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const

void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const

void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const

std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesDependentUpon (const std::string &iProcessName, std::vector< const char * > &oModuleLabels) const

bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)

virtual	~EDConsumerBase ()

Private Member Functions
void	SetEtaLabels (MonitorElement *h)

Private Attributes
std::map< HcalDetId, int >	BadCells_

MonitorElement *	CenterOfEnergy

MonitorElement *	CenterOfEnergyRadius

MonitorElement *	COEradiusVSeta

edm::InputTag	digiLabel_

MonitorElement *	Energy_Occ

const int	ETA_BOUND_HE

const int	ETA_BOUND_HF

const int	ETA_OFFSET_HB

const int	ETA_OFFSET_HE

const int	ETA_OFFSET_HF

const int	ETA_OFFSET_HO

MonitorElement *	Etsum_eta_L

MonitorElement *	Etsum_eta_S

MonitorElement *	Etsum_map_L

MonitorElement *	Etsum_map_S

MonitorElement *	Etsum_phi_L

MonitorElement *	Etsum_phi_S

MonitorElement *	Etsum_ratio_m

MonitorElement *	Etsum_ratio_map

MonitorElement *	Etsum_ratio_p

MonitorElement *	Etsum_rphi_L

MonitorElement *	Etsum_rphi_S

std::map< int, MonitorElement * >	HB_CenterOfEnergyRadius

MonitorElement *	HBCenterOfEnergy

MonitorElement *	HBCenterOfEnergyRadius

edm::InputTag	hbheRechitLabel_

std::map< int, MonitorElement * >	HE_CenterOfEnergyRadius

MonitorElement *	HECenterOfEnergy

MonitorElement *	HECenterOfEnergyRadius

std::map< int, MonitorElement * >	HF_CenterOfEnergyRadius

MonitorElement *	HFCenterOfEnergy

MonitorElement *	HFCenterOfEnergyRadius

MonitorElement *	HFlumi_diag_deadcells

MonitorElement *	HFlumi_diag_hotcells

MonitorElement *	HFlumi_Et_per_channel_vs_lumiblock

MonitorElement *	HFlumi_ETsum_perwedge

MonitorElement *	HFlumi_ETsum_vs_BX

MonitorElement *	HFlumi_occ_LS

MonitorElement *	HFlumi_Occupancy_above_thr_r1

MonitorElement *	HFlumi_Occupancy_above_thr_r2

MonitorElement *	HFlumi_Occupancy_below_thr_r1

MonitorElement *	HFlumi_Occupancy_below_thr_r2

MonitorElement *	HFlumi_Occupancy_between_thrs_r1

MonitorElement *	HFlumi_Occupancy_between_thrs_r2

MonitorElement *	HFlumi_Occupancy_per_channel_vs_BX_RING1

MonitorElement *	HFlumi_Occupancy_per_channel_vs_BX_RING2

MonitorElement *	HFlumi_Occupancy_per_channel_vs_lumiblock_RING1

MonitorElement *	HFlumi_Occupancy_per_channel_vs_lumiblock_RING2

MonitorElement *	HFlumi_Ring1Status_vs_LS

MonitorElement *	HFlumi_Ring2Status_vs_LS

MonitorElement *	HFlumi_total_deadcells

MonitorElement *	HFlumi_total_hotcells

edm::InputTag	hfRechitLabel_

std::map< int, MonitorElement * >	HO_CenterOfEnergyRadius

MonitorElement *	HOCenterOfEnergy

MonitorElement *	HOCenterOfEnergyRadius

edm::InputTag	hoRechitLabel_

double	hotrate_

unsigned int	lastProcessedLS_

std::string	lumiqualitydir_

int	minBadCells_

int	minEvents_

MonitorElement *	Occ_eta_L

MonitorElement *	Occ_eta_S

MonitorElement *	Occ_map_L

MonitorElement *	Occ_map_S

MonitorElement *	Occ_phi_L

MonitorElement *	Occ_phi_S

MonitorElement *	Occ_rphi_L

MonitorElement *	Occ_rphi_S

double	occThresh_

std::ostringstream	outfile_

bool	Overwrite_

int	ring1totalchannels_

int	ring2totalchannels_

int	runNumber_

bool	setupDone_

edm::EDGetTokenT < HBHERecHitCollection >	tok_hbhe_

edm::EDGetTokenT < HFRecHitCollection >	tok_hf_

edm::EDGetTokenT < HFDigiCollection >	tok_hfdigi_

edm::EDGetTokenT < HORecHitCollection >	tok_ho_

Static Private Attributes
static const float	area [] ={0.111,0.175,0.175,0.175,0.175,0.175,0.174,0.178,0.172,0.175,0.178,0.346,0.604}

static const float	radius [] ={1300,1162,975,818,686,576,483,406,340,286,240,201,169}

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType

Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string &	baseType ()

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &)

Protected Member Functions inherited from HcalBaseDQMonitor
virtual void	beginJob ()

virtual void	endJob (void)

virtual void	endRun (const edm::Run &run, const edm::EventSetup &c)

void	getLogicalMap (const edm::EventSetup &c)

bool	IsAllowedCalibType ()

bool	LumiInOrder (int lumisec)

void	SetupEtaPhiHists (EtaPhiHists &hh, std::string Name, std::string Units)

Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)

EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)

ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...

template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()

void	consumesMany (const TypeToGet &id)

template<BranchType B>
void	consumesMany (const TypeToGet &id)

template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Protected Attributes inherited from HcalBaseDQMonitor
std::vector< int >	AllowedCalibTypes_

int	badChannelStatusMask_

int	currentLS

int	currenttype_

DQMStore *	dbe_

int	debug_

bool	enableCleanup_

bool	eventAllowed_

bool	HBpresent_

bool	HEpresent_

bool	HFpresent_

bool	HOpresent_

int	ievt_

std::map< unsigned int, int >	KnownBadCells_

int	levt_

HcalLogicalMap *	logicalMap_

bool	makeDiagnostics_

MonitorElement *	meIevt_

MonitorElement *	meLevt_

bool	mergeRuns_

MonitorElement *	meTevt_

MonitorElement *	meTevtHist_

bool	needLogicalMap_

int	NLumiBlocks_

bool	Online_

std::string	prefixME_

MonitorElement *	ProblemsCurrentLB

MonitorElement *	ProblemsVsLB

MonitorElement *	ProblemsVsLB_HB

MonitorElement *	ProblemsVsLB_HBHEHF

MonitorElement *	ProblemsVsLB_HE

MonitorElement *	ProblemsVsLB_HF

MonitorElement *	ProblemsVsLB_HO

bool	skipOutOfOrderLS_

std::string	subdir_

int	tevt_

Detailed Description

Author: J. Temple - Univ. of Maryland

Definition at line 21 of file HcalBeamMonitor.h.

Constructor & Destructor Documentation

HcalBeamMonitor::HcalBeamMonitor ( const edm::ParameterSet & ps )

Definition at line 29 of file HcalBeamMonitor.cc.

                                                          :
   ETA_OFFSET_HB(16),
   ETA_OFFSET_HE(29),
   ETA_BOUND_HE(17),
   ETA_OFFSET_HO(15),
   ETA_OFFSET_HF(41),
   ETA_BOUND_HF(29)
 {
   Online_                = ps.getUntrackedParameter<bool>("online",false);
   mergeRuns_             = ps.getUntrackedParameter<bool>("mergeRuns",false);
   enableCleanup_         = ps.getUntrackedParameter<bool>("enableCleanup",false);
   debug_                 = ps.getUntrackedParameter<int>("debug",0);
   prefixME_              = ps.getUntrackedParameter<std::string>("subSystemFolder","Hcal/");
   if (prefixME_.substr(prefixME_.size()-1,prefixME_.size())!="/")
     prefixME_.append("/");
   subdir_                = ps.getUntrackedParameter<std::string>("TaskFolder","BeamMonitor_Hcal");
   if (subdir_.size()>0 && subdir_.substr(subdir_.size()-1,subdir_.size())!="/")
     subdir_.append("/");
   subdir_=prefixME_+subdir_;
   AllowedCalibTypes_     = ps.getUntrackedParameter<std::vector<int> > ("AllowedCalibTypes");
   skipOutOfOrderLS_      = ps.getUntrackedParameter<bool>("skipOutOfOrderLS",true);
   NLumiBlocks_           = ps.getUntrackedParameter<int>("NLumiBlocks",4000);
   makeDiagnostics_       = ps.getUntrackedParameter<bool>("makeDiagnostics",false);
 
   // Beam Monitor-specific stuff
 
   // Collection type info
   digiLabel_             =ps.getUntrackedParameter<edm::InputTag>("digiLabel");
   tok_hfdigi_ = consumes<HFDigiCollection>(digiLabel_);
   hbheRechitLabel_       = ps.getUntrackedParameter<edm::InputTag>("hbheRechitLabel");
 
   tok_hbhe_ = consumes<HBHERecHitCollection>(hbheRechitLabel_);
 
   hoRechitLabel_         = ps.getUntrackedParameter<edm::InputTag>("hoRechitLabel");
   tok_ho_ = consumes<HORecHitCollection>(hoRechitLabel_);
 
   hfRechitLabel_         = ps.getUntrackedParameter<edm::InputTag>("hfRechitLabel");
   tok_hf_ = consumes<HFRecHitCollection>(hfRechitLabel_);
 
   // minimum events required in lumi block for tests to be processed
   minEvents_       = ps.getUntrackedParameter<int>("minEvents",500); 
   lumiqualitydir_ = ps.getUntrackedParameter<std::string>("lumiqualitydir","");
   if (lumiqualitydir_.size()>0 && lumiqualitydir_.substr(lumiqualitydir_.size()-1,lumiqualitydir_.size())!="/")
     lumiqualitydir_.append("/");
   occThresh_ = ps.getUntrackedParameter<double>("occupancyThresh",0.0625);  // energy required to be counted by dead/hot checks
   hotrate_        = ps.getUntrackedParameter<double>("hotrate",0.25);
   minBadCells_    = ps.getUntrackedParameter<int>("minBadCells",10);
   Overwrite_      = ps.getUntrackedParameter<bool>("Overwrite",false);
   setupDone_      = false;
 }

HcalBeamMonitor::~HcalBeamMonitor ( )

Definition at line 82 of file HcalBeamMonitor.cc.

82 {}

Member Function Documentation

void HcalBeamMonitor::analyze	(	const edm::Event &	e,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 474 of file HcalBeamMonitor.cc.

References HcalBaseDQMonitor::analyze(), edm::EventBase::bunchCrossing(), digiLabel_, edm::Event::getByToken(), hbheRechitLabel_, hfRechitLabel_, hoRechitLabel_, HcalBaseDQMonitor::IsAllowedCalibType(), HcalBaseDQMonitor::LumiInOrder(), edm::EventBase::luminosityBlock(), processEvent(), tok_hbhe_, tok_hf_, tok_hfdigi_, and tok_ho_.

 {
   if (!IsAllowedCalibType()) return;
   if (LumiInOrder(e.luminosityBlock())==false) return;
 
   // try to get rechits and digis
   edm::Handle<HFDigiCollection> hf_digi;
 
   edm::Handle<HBHERecHitCollection> hbhe_rechit;
   edm::Handle<HORecHitCollection> ho_rechit;
   edm::Handle<HFRecHitCollection> hf_rechit;
   
   if (!(e.getByToken(tok_hfdigi_,hf_digi)))
     {
       edm::LogWarning("HcalBeamMonitor")<< digiLabel_<<" hf_digi not available";
       return;
     }
 
   if (!(e.getByToken(tok_hbhe_,hbhe_rechit)))
     {
       edm::LogWarning("HcalBeamMonitor")<< hbheRechitLabel_<<" hbhe_rechit not available";
       return;
     }
 
   if (!(e.getByToken(tok_hf_,hf_rechit)))
     {
       edm::LogWarning("HcalBeamMonitor")<< hfRechitLabel_<<" hf_rechit not available";
       return;
     }
   if (!(e.getByToken(tok_ho_,ho_rechit)))
     {
       edm::LogWarning("HcalBeamMonitor")<< hoRechitLabel_<<" ho_rechit not available";
       return;
     }
 
   //good event; increment counters and process
   HcalBaseDQMonitor::analyze(e,c);
   processEvent(*hbhe_rechit, *ho_rechit, *hf_rechit, *hf_digi, e.bunchCrossing());
 
 } //void HcalBeamMonitor::analyze(const edm::Event& e, const edm::EventSetup& c)

void HcalBeamMonitor::beginLuminosityBlock	(	const edm::LuminosityBlock &	lumiSeg,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 1121 of file HcalBeamMonitor.cc.

References HcalBaseDQMonitor::beginLuminosityBlock(), HcalBaseDQMonitor::currentLS, MonitorElement::getTH2F(), HFlumi_occ_LS, lastProcessedLS_, HcalBaseDQMonitor::LumiInOrder(), edm::LuminosityBlockBase::luminosityBlock(), HcalBaseDQMonitor::ProblemsCurrentLB, MonitorElement::Reset(), and indexGen::title.

 {
   // reset histograms that get updated each luminosity section
 
   if (LumiInOrder(lumiSeg.luminosityBlock())==false) return;
   HcalBaseDQMonitor::beginLuminosityBlock(lumiSeg,c);
 
   if (lumiSeg.luminosityBlock()==lastProcessedLS_) return; // we're seeing more events from current lumi section (after some break) -- should not reset histogram
   ProblemsCurrentLB->Reset();
   HFlumi_occ_LS->Reset();
   std::stringstream title;
   title <<"HFlumi occupancy for LS # " <<currentLS;
   HFlumi_occ_LS->getTH2F()->SetTitle(title.str().c_str());
   return;
 } // void HcalBeamMonitor::beginLuminosityBlock()

void HcalBeamMonitor::beginRun	(	const edm::Run &	run,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 404 of file HcalBeamMonitor.cc.

References funct::abs(), BadCells_, HcalBaseDQMonitor::beginRun(), gather_cfg::cout, HcalBaseDQMonitor::debug_, edm::EventSetup::get(), HcalCondObjectContainer< Item >::getAllChannels(), HcalChannelStatus::getValue(), HcalCondObjectContainer< Item >::getValues(), DetId::Hcal, HcalChannelStatus::HcalCellDead, HcalChannelStatus::HcalCellHot, HcalForward, i, edm::RunBase::id(), HcalChannelStatus::isBitSet(), lastProcessedLS_, lumiqualitydir_, HcalBaseDQMonitor::mergeRuns_, HcalBaseDQMonitor::Online_, outfile_, Overwrite_, AlCaHLTBitMon_ParallelJobs::p, edm::ESHandle< class >::product(), HcalChannelStatus::rawId(), reset(), ring1totalchannels_, ring2totalchannels_, edm::RunID::run(), runNumber_, setup(), and HcalBaseDQMonitor::tevt_.

 {
   HcalBaseDQMonitor::beginRun(run,c);  
 
   if (debug_>1) std::cout <<"HcalBeamMonitor::beginRun"<<std::endl;
   HcalBaseDQMonitor::beginRun(run,c);
 
   lastProcessedLS_=0;
   runNumber_=run.id().run();
   if (lumiqualitydir_.size()>0 && Online_==true)
     {
       if (Overwrite_==false)
     outfile_ <<lumiqualitydir_<<"HcalHFLumistatus_"<<runNumber_<<".txt";
       else
     outfile_ <<lumiqualitydir_<<"HcalHFLumistatus.txt";
       std::ofstream outStream(outfile_.str().c_str()); // recreate the file, rather than appending to it
       outStream<<"## Run "<<runNumber_<<std::endl;
       outStream<<"## LumiBlock\tRing1Status\t\tRing2Status\t\tGlobalStatus\tNentries"<<std::endl;
       outStream.close();
     }
 
   // Get expected good channels in run according to channel quality database
   // Get channel quality status info for each run
 
   // Default number of expected good channels in the run
   ring1totalchannels_=144;
   ring2totalchannels_=144;
   BadCells_.clear(); // remove any old maps
   // Get Channel quality info for the run
   // Exclude bad channels from overall calculation
   edm::ESHandle<HcalChannelQuality> p;
   c.get<HcalChannelQualityRcd>().get(p);
   HcalChannelQuality* chanquality = new HcalChannelQuality(*p.product());
   std::vector<DetId> mydetids = chanquality->getAllChannels();
   
   for (unsigned int i=0;i<mydetids.size();++i)
     {
       if (mydetids[i].det()!=DetId::Hcal) continue;
       HcalDetId id=mydetids[i];
       
       if (id.subdet()!=HcalForward) continue;
       if ((id.depth()==1 && (abs(id.ieta())==33 || abs(id.ieta())==34)) ||
       (id.depth()==2 && (abs(id.ieta())==35 || abs(id.ieta())==36)))
     {
       const HcalChannelStatus* origstatus=chanquality->getValues(id);
       HcalChannelStatus* mystatus=new HcalChannelStatus(origstatus->rawId(),origstatus->getValue());
       if (mystatus->isBitSet(HcalChannelStatus::HcalCellHot)) 
         BadCells_[id]=HcalChannelStatus::HcalCellHot;
       
       else if (mystatus->isBitSet(HcalChannelStatus::HcalCellDead))
         BadCells_[id]=HcalChannelStatus::HcalCellDead;
       
       if (mystatus->isBitSet(HcalChannelStatus::HcalCellHot) || 
           mystatus->isBitSet(HcalChannelStatus::HcalCellDead))
         {
           if (id.depth()==1) --ring1totalchannels_;
           else if (id.depth()==2) --ring2totalchannels_;
         }
       delete mystatus;
     } // if ((id.depth()==1) ...
     } // for (unsigned int i=0;...)
     
   if (tevt_==0) this->setup(); // create all histograms; not necessary if merging runs together
   if (mergeRuns_==false) this->reset(); // call reset at start of all runs
 
   return;
 
 } // void HcalBeamMonitor::beginRun(const edm::Run& run, const edm::EventSetup& c)

void HcalBeamMonitor::cleanup ( void )

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 147 of file HcalBeamMonitor.cc.

References HcalBaseDQMonitor::dbe_, DQMStore::removeContents(), DQMStore::setCurrentFolder(), and HcalBaseDQMonitor::subdir_.

 {
   if (dbe_) 
     {
       dbe_->setCurrentFolder(subdir_);
       dbe_->removeContents();
       dbe_->setCurrentFolder(subdir_+"LSvalues");
       dbe_->removeContents();
     } // if (dbe_)
 } // void HcalBeamMonitor::cleanup()

void HcalBeamMonitor::endLuminosityBlock	(	const edm::LuminosityBlock &	lumiSeg,
		const edm::EventSetup &	c
	)

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 1139 of file HcalBeamMonitor.cc.

References funct::abs(), BadCells_, gather_cfg::cout, HcalBaseDQMonitor::currentLS, HcalBaseDQMonitor::debug_, MonitorElement::Fill(), MonitorElement::getBinContent(), MonitorElement::getTH2F(), HcalForward, HFlumi_diag_deadcells, HFlumi_diag_hotcells, HFlumi_occ_LS, HFlumi_Ring1Status_vs_LS, HFlumi_Ring2Status_vs_LS, HFlumi_total_deadcells, HFlumi_total_hotcells, hotrate_, lastProcessedLS_, HcalBaseDQMonitor::levt_, HcalBaseDQMonitor::LumiInOrder(), edm::LuminosityBlockBase::luminosityBlock(), lumiqualitydir_, minBadCells_, minEvents_, HcalBaseDQMonitor::Online_, outfile_, HcalBaseDQMonitor::ProblemsCurrentLB, ring1totalchannels_, ring2totalchannels_, x, and detailsBasic3DVector::y.

 {
   if (debug_>1) std::cout <<"<HcalBeamMonitor::endLuminosityBlock>"<<std::endl;
   if (LumiInOrder(lumiSeg.luminosityBlock())==false)
     {
       if (debug_>1)  
     std::cout <<"<HcalBeamMonitor::endLuminosityBlock>  Failed LumiInOrder test!"<<std::endl;
       return;
     }
   lastProcessedLS_=lumiSeg.luminosityBlock();
   float Nentries=HFlumi_occ_LS->getBinContent(-1,-1);
   if (debug_>3) 
     std::cout <<"Number of entries in this LB = "<<Nentries<<std::endl;
 
   if (Nentries<minEvents_) 
     {
       // not enough entries to determine status; fill everything with -1 and return
       HFlumi_Ring1Status_vs_LS->Fill(currentLS,-1);
       HFlumi_Ring2Status_vs_LS->Fill(currentLS,-1);
       if (Online_==false)
     return;
       // write to output file if required (Online running)
       if (lumiqualitydir_.size()==0)
     return;
       // dump out lumi quality file
       std::ofstream outStream(outfile_.str().c_str(),std::ios::app);
       outStream<<currentLS<<"\t\t-1\t\t\t-1\t\t\t-1\t\t"<<Nentries<<std::endl;
       outStream.close();
       return;
     }
   if (Nentries==0) return;
 
 
   HFlumi_total_deadcells->Fill(-1,-1,1); // counts good lumi sections in underflow bin
   HFlumi_total_hotcells->Fill(-1,-1,1);
   HFlumi_diag_deadcells->Fill(-1,-1,1); // counts good lumi sections in underflow bin
   HFlumi_diag_hotcells->Fill(-1,-1,1);
 
   // ADD IETA MAP
   int ietamap[8]={-36,-35,-34,-33,33,34,35,36};
   int ieta=-1, iphi = -1, depth=-1;
   int badring1=0;
   int badring2=0;
   int ndeadcells=0;
   int nhotcells=0;
   
   // Loop over cells once to count hot & dead chanels
   for (int x=1;x<=HFlumi_occ_LS->getTH2F()->GetNbinsX();++x)
     {
       for (int y=1;y<=HFlumi_occ_LS->getTH2F()->GetNbinsY();++y)
     {
 
       // Skip over channels that are flagged as bad
       if (x<=8)
         ieta=ietamap[x-1];
       else
         ieta=-1;
       iphi=2*y-1;
       if (abs(ieta)==33 || abs(ieta)==34)  depth=1;
       else if (abs(ieta)==35 || abs(ieta)==36) depth =2;
       else depth = -1;
       if (depth !=-1 && ieta!=1)
         {
           HcalDetId thisID(HcalForward, ieta, iphi, depth);
           if (BadCells_.find(thisID)!=BadCells_.end())
         continue;
         }
       double Ncellhits=HFlumi_occ_LS->getBinContent(x,y);
       if (Ncellhits==0)
         {
           ++ndeadcells;
           HFlumi_diag_deadcells->Fill(x-1,2*y-1,1);
         }
       // hot if present in more than 25% of events in the LS
       if (Ncellhits>hotrate_*Nentries) 
         {
           ++nhotcells;
           HFlumi_diag_hotcells->Fill(x-1,2*y-1,1);
         }
       if (Ncellhits==0 || Ncellhits>hotrate_*Nentries) // cell was either hot or dead
         {
           if (depth==1)  badring1++;
           else if (depth==2)  badring2++;
         }
     } // loop over y
     } // loop over x
 
   // Fill problem histogram underflow bind with number of events
   ProblemsCurrentLB->Fill(-1,-1,levt_);
   if (ndeadcells+nhotcells>=minBadCells_)
     {
       // Fill with number of error channels * events (assume bad for all events in LS)
       ProblemsCurrentLB->Fill(6,0,(ndeadcells+nhotcells)*levt_);
       for (int x=1;x<=HFlumi_occ_LS->getTH2F()->GetNbinsX();++x)
     {
       for (int y=1;y<=HFlumi_occ_LS->getTH2F()->GetNbinsY();++y)
         {
           if (x<=8)
         ieta=ietamap[x-1];
           else
         ieta=-1;
           iphi=2*y-1;
           if (abs(ieta)==33 || abs(ieta)==34)  depth=1;
           else if (abs(ieta)==35 || abs(ieta)==36) depth =2;
           else depth = -1;
           if (depth !=-1 && ieta!=1)
         {
           // skip over channels that are flagged as bad
           HcalDetId thisID(HcalForward, ieta, iphi, depth);
           if (BadCells_.find(thisID)!=BadCells_.end())
             continue;
         }
           double Ncellhits=HFlumi_occ_LS->getBinContent(x,y);
           if (Ncellhits==0)
         {
           // One new luminosity section found with no entries for the cell in question
           HFlumi_total_deadcells->Fill(x-1,2*y-1,1);
         } // dead cell check
           
           // hot if present in more than 25% of events in the LS
           if (Ncellhits>hotrate_*Nentries)
         {
           HFlumi_total_hotcells->Fill(x-1,2*y-1,1);
         } // hot cell check
         } // loop over y
     } // loop over x
     } // if (ndeadcells+nhotcells>=minBadCells_)
 
   // Fill fraction of bad channels found in this LS
   double ring1status=0;
   double ring2status=0;
   if (ring1totalchannels_==0)
     ring1status=0;
   else
     ring1status=1-1.*badring1/ring1totalchannels_;
   HFlumi_Ring1Status_vs_LS->Fill(currentLS,ring1status);
   if (ring2totalchannels_==0)
     ring2status=0;
   else
     ring2status=1-1.*badring2/ring2totalchannels_;
   HFlumi_Ring2Status_vs_LS->Fill(currentLS,ring2status);  
   
   // Good status:  ring1 and ring2 status both > 90%
   int totalstatus=0;
   if (ring1status>0.9 && ring2status>0.9)
     totalstatus=1;
   else 
     {
       if (ring1status<=0.9)
     totalstatus-=2;
       if (ring2status<=0.9)
     totalstatus-=4;
     }
 
   if (lumiqualitydir_.size()==0)
     return;
   // dump out lumi quality file
   std::ofstream outStream(outfile_.str().c_str(),std::ios::app);
   outStream.precision(6);
   outStream<<currentLS<<"\t\t"<<ring1status<<"\t\t"<<ring2status<<"\t\t"<<totalstatus<<"\t\t"<<Nentries<<std::endl;
   outStream.close();
   return;
 }

void HcalBeamMonitor::processEvent	(	const HBHERecHitCollection &	hbHits,
		const HORecHitCollection &	hoHits,
		const HFRecHitCollection &	hfHits,
		const HFDigiCollection &	hf,
		int	bunchCrossing
	)

Definition at line 516 of file HcalBeamMonitor.cc.

Referenced by analyze().

 { 
   //processEvent loop
   if (!dbe_)
     {
       if (debug_>0) std::cout <<"HcalBeamMonitor::processEvent   DQMStore not instantiated!!!"<<std::endl;
       return;
     }
 
   HBHERecHitCollection::const_iterator HBHEiter;
   HORecHitCollection::const_iterator HOiter;
   HFRecHitCollection::const_iterator HFiter;
 
   double totalX=0;
   double totalY=0;
   double totalE=0;
 
   double HBtotalX=0;
   double HBtotalY=0;
   double HBtotalE=0;
   double HEtotalX=0;
   double HEtotalY=0;
   double HEtotalE=0;
   double HOtotalX=0;
   double HOtotalY=0;
   double HOtotalE=0;
   double HFtotalX=0;
   double HFtotalY=0;
   double HFtotalE=0;
      
   float hitsp[13][36][2];
   float hitsm[13][36][2];
   float hitsp_Et[13][36][2];
   float hitsm_Et[13][36][2];
   
   for(int m=0;m<13;m++){
     for(int n=0;n<36;n++){
       hitsp[m][n][0]=0;
       hitsp[m][n][1]=0; 
       hitsm[m][n][0]=0;
       hitsm[m][n][1]=0;
 
       hitsp_Et[m][n][0]=0;
       hitsp_Et[m][n][1]=0; 
       hitsm_Et[m][n][0]=0;
       hitsm_Et[m][n][1]=0;
     }
   }
 
   if(hbheHits.size()>0)
     {
       double HB_weightedX[HBETASIZE]={0.};
       double HB_weightedY[HBETASIZE]={0.};
       double HB_energy[HBETASIZE]={0.};
       
       double HE_weightedX[HEETASIZE]={0.};
       double HE_weightedY[HEETASIZE]={0.};
       double HE_energy[HEETASIZE]={0.};
       
       int ieta, iphi;
       
       for (HBHEiter=hbheHits.begin(); 
        HBHEiter!=hbheHits.end(); 
        ++HBHEiter) 
     { 
       
       // loop over all hits
       if (HBHEiter->energy()<0) continue; // don't consider negative-energy cells
       HcalDetId id(HBHEiter->detid().rawId());
       ieta=id.ieta();
       iphi=id.iphi();
       
       int index=-1;
       if ((HcalSubdetector)(id.subdet())==HcalBarrel)
         {
           HBtotalX+=HBHEiter->energy()*cos(PI*iphi/36.);
           HBtotalY+=HBHEiter->energy()*sin(PI*iphi/36.);
           HBtotalE+=HBHEiter->energy();
           
           index=ieta+ETA_OFFSET_HB;
           if (index<0 || index>= HBETASIZE) continue;
           HB_weightedX[index]+=HBHEiter->energy()*cos(PI*iphi/36.);
           HB_weightedY[index]+=HBHEiter->energy()*sin(PI*iphi/36.);
           HB_energy[index]+=HBHEiter->energy();
         } // if id.subdet()==HcalBarrel
       
       else
         {
           HEtotalX+=HBHEiter->energy()*cos(PI*iphi/36.);
           HEtotalY+=HBHEiter->energy()*sin(PI*iphi/36.);
           HEtotalE+=HBHEiter->energy();
           
           index=ieta+ETA_OFFSET_HE;
           if (index<0 || index>= HEETASIZE) continue;
           HE_weightedX[index]+=HBHEiter->energy()*cos(PI*iphi/36.);
           HE_weightedY[index]+=HBHEiter->energy()*sin(PI*iphi/36.);
           HE_energy[index]+=HBHEiter->energy();
         }
     } // for (HBHEiter=hbheHits.begin()...
       // Fill each histogram
       
       int hbeta=ETA_OFFSET_HB;
       for (int i=-1*hbeta;i<=hbeta;++i)
     {
       if (i==0) continue;
       int index = i+ETA_OFFSET_HB;
       if (index<0 || index>= HBETASIZE) continue;
       if (HB_energy[index]==0) continue;
       double moment=pow(HB_weightedX[index],2)+pow(HB_weightedY[index],2);
       moment=pow(moment,0.5);
       moment/=HB_energy[index];
       if (moment!=0)
         {
           if (makeDiagnostics_) HB_CenterOfEnergyRadius[index]->Fill(moment);
           COEradiusVSeta->Fill(i,moment);
         }
     } // for (int i=-1*hbeta;i<=hbeta;++i)
 
       int heeta=ETA_OFFSET_HE;
       for (int i=-1*heeta;i<=heeta;++i)
     {
       if (i==0) continue;
       if (i>-1*ETA_BOUND_HE && i <ETA_BOUND_HE) continue;
       int index = i + ETA_OFFSET_HE;
       if (index<0 || index>= HEETASIZE) continue;
       if (HE_energy[index]==0) continue;
       double moment=pow(HE_weightedX[index],2)+pow(HE_weightedY[index],2);
       moment=pow(moment,0.5);
       moment/=HE_energy[index];
       if (moment!=0)
         {
           if (makeDiagnostics_) HE_CenterOfEnergyRadius[index]->Fill(moment);
           COEradiusVSeta->Fill(i,moment);
         }
     } // for (int i=-1*heeta;i<=heeta;++i)
 
     } // if (hbheHits.size()>0)
 
   
   // HO loop
   if(hoHits.size()>0)
     {
       double HO_weightedX[HOETASIZE]={0.};
       double HO_weightedY[HOETASIZE]={0.};
       double HO_energy[HOETASIZE]={0.};
       double offset;
 
       int ieta, iphi;
       for (HOiter=hoHits.begin(); 
        HOiter!=hoHits.end(); 
        ++HOiter) 
     { 
       // loop over all cells
       if (HOiter->energy()<0) continue;  // don't include negative-energy cells?
       HcalDetId id(HOiter->detid().rawId());
       ieta=id.ieta();
       iphi=id.iphi();
 
       HOtotalX+=HOiter->energy()*cos(PI*iphi/36.);
       HOtotalY+=HOiter->energy()*sin(PI*iphi/36.);
       HOtotalE+=HOiter->energy();
 
       int index=ieta+ETA_OFFSET_HO;
       if (index<0 || index>= HOETASIZE) continue;
       HO_weightedX[index]+=HOiter->energy()*cos(PI*iphi/36.);
       HO_weightedY[index]+=HOiter->energy()*sin(PI*iphi/36.);
       HO_energy[index]+=HOiter->energy();
     } // for (HOiter=hoHits.begin();...)
       
       for (int i=-1*ETA_OFFSET_HO;i<=ETA_OFFSET_HO;++i)
     {
       if (i==0) continue;
       int index = i + ETA_OFFSET_HO;
       if (index < 0 || index>= HOETASIZE) continue;
       if (HO_energy[index]==0) continue;
       double moment=pow(HO_weightedX[index],2)+pow(HO_weightedY[index],2);
       moment=pow(moment,0.5);
       moment/=HO_energy[index];
       // Shift HO values by 0.5 units in eta relative to HB
       offset = (i>0 ? 0.5: -0.5);
       if (moment!=0)
         {
           if (makeDiagnostics_) HO_CenterOfEnergyRadius[index]->Fill(moment);
           COEradiusVSeta->Fill(i+offset,moment);
         }
     } // for (int i=-1*hoeta;i<=hoeta;++i)
     } // if (hoHits.size()>0)
     
   // HF loop
 
   Etsum_ratio_map->Fill(-1,-1,1); // fill underflow bin with number of events
   {
     if(hfHits.size()>0)
       {
     double HF_weightedX[HFETASIZE]={0.};
     double HF_weightedY[HFETASIZE]={0.};
     double HF_energy[HFETASIZE]={0.};
     double offset;
     
     // Assume ZS until shown otherwise
     double emptytowersRing1 = ring1totalchannels_;
     double emptytowersRing2 = ring2totalchannels_;
     double ZStowersRing1 = ring1totalchannels_;
     double ZStowersRing2 = ring2totalchannels_;
     
     int ieta, iphi;
     float et,eta,phi,r;
 
     HFlumi_occ_LS->Fill(-1,-1,1 ); // event counter in occupancy histogram underflow bin
     // set maximum to HFlumi_occ_LS->getBinContent(0,0)?  
     // that won't work -- offline will add multiple histograms, and maximum will get screwed up?
     // No, we can add it here, but we also need a call to setMaximum in the client as well.
     HFlumi_occ_LS->getTH2F()->SetMaximum(HFlumi_occ_LS->getBinContent(0,0));
 
     double etx=0, ety=0;
 
     for (HFiter=hfHits.begin(); 
          HFiter!=hfHits.end(); 
          ++HFiter) 
       {  // loop on hfHits
         // If hit present, don't count it as ZS any more
         ieta = HFiter->id().ieta();
         iphi = HFiter->id().iphi();
 
         int binieta=ieta;
         if (ieta<0) binieta+=41;
         else if (ieta>0) binieta-=15;
 
         // Count that hit was found in one of the rings used for luminosity calculation.
         // If so, decrease the number of empty channels per ring by 1
         if (abs(ieta)>=33 && abs(ieta)<=36) // luminosity ring check
           {
         // don't subtract away cells that have already been removed as bad
         if (BadCells_.find(HFiter->id())==BadCells_.end()) // bad cell not found
           {
             if ((abs(ieta)<35) && HFiter->id().depth()==1) --ZStowersRing1;
             else if ((abs(ieta)>34) && HFiter->id().depth()==2) -- ZStowersRing2;
           }
           }
 
         if (HFiter->energy()<0) continue;  // don't include negative-energy cells?
 
         eta=theHFEtaBounds[abs(ieta)-29];
         et=HFiter->energy()/cosh(eta)/area[abs(ieta)-29];
         if (abs(ieta)>=33 && abs(ieta)<=36) // Luminosity ring check
           {
         // don't count cells that are below threshold, or that have been marked bad in Chan Stat DB
         if (et>=occThresh_ && BadCells_.find(HFiter->id())==BadCells_.end() ) // minimum ET threshold
           {
             if ((abs(ieta)<35) && HFiter->id().depth()==1) --emptytowersRing1;
             else if ((abs(ieta)>34) && HFiter->id().depth()==2) -- emptytowersRing2;
           }
           }
         r=radius[abs(ieta)-29];
         if(HFiter->id().iphi()<37)
           phi=HFiter->id().iphi()*0.087266;
         else phi=(HFiter->id().iphi()-72)*0.087266;
            
         
         if (HFiter->id().depth()==1)
           {
         Etsum_eta_L->Fill(binieta,et);
         Etsum_phi_L->Fill(iphi,et);
         Etsum_map_L->Fill(binieta,iphi,et);
         Etsum_rphi_L->Fill(r,phi,et);
           
         if(ieta>0) {
           hitsp[ieta-29][(HFiter->id().iphi()-1)/2][0]=HFiter->energy();
           hitsp_Et[ieta-29][(HFiter->id().iphi()-1)/2][0]=et;
         }
         else if(ieta<0) {
           hitsm[-ieta-29][(HFiter->id().iphi()-1)/2][0]=HFiter->energy(); 
           hitsm_Et[-ieta-29][(HFiter->id().iphi()-1)/2][0]=et; 
         }
           } // if (HFiter->id().depth()==1)
          
         //Fill 3 histos for Short Fibers :
         if (HFiter->id().depth()==2)
           {
         Etsum_eta_S->Fill(binieta,et);
         Etsum_phi_S->Fill(iphi,et);
         Etsum_rphi_S->Fill(r,phi,et); 
         Etsum_map_S->Fill(binieta,iphi,et);
         if(ieta>0)  
           {
             hitsp[ieta-29][(HFiter->id().iphi()-1)/2][1]=HFiter->energy();
             hitsp_Et[ieta-29][(HFiter->id().iphi()-1)/2][1]=et;
           }
         else if(ieta<0)  { 
           hitsm[-ieta-29][(HFiter->id().iphi()-1)/2][1]=HFiter->energy();
           hitsm_Et[-ieta-29][(HFiter->id().iphi()-1)/2][1]=et;
         }
           
           } // depth()==2
         Energy_Occ->Fill(HFiter->energy()); 
             
         //HF: no non-threshold occupancy map is filled?
 
         if ((abs(ieta) == 33 || abs(ieta) == 34) && HFiter->id().depth() == 1)
           { 
         etx+=et*cos(PI*iphi/36.);
         ety+=et*sin(PI*iphi/36.);
 
         HFlumi_Et_per_channel_vs_lumiblock->Fill(currentLS,et);
         if (et>occThresh_)
           {
             int etabin=0;
             if (ieta<0)
               etabin=36+ieta; // bins 0-3 correspond to ieta = -36, -35, -34, -33
             else
               etabin=ieta-29; // bins 4-7 correspond to ieta = 33, 34, 35, 36
             HFlumi_occ_LS->Fill(etabin,HFiter->id().iphi());
           }
           }
 
         else if ((abs(ieta) == 35 || abs(ieta) == 36) && HFiter->id().depth() == 2)
           { 
         etx+=et*cos(PI*iphi/36.);
         ety+=et*sin(PI*iphi/36.);
 
         HFlumi_Et_per_channel_vs_lumiblock->Fill(currentLS,et);
         if (et>occThresh_)
           {
             int etabin=0;
             if (ieta<0)
               etabin=36+ieta; // bins 0-3 correspond to ieta = -36, -35, -34, -33
             else
               etabin=ieta-29; // bins 4-7 correspond to ieta = 33, 34, 35, 36
             HFlumi_occ_LS->Fill(etabin,HFiter->id().iphi());
           }
           }
 
         // Fill occupancy plots.
         
         int value=0;
         if(et>occThresh_) value=1;
 
         if (HFiter->id().depth()==1)
           {
         Occ_eta_L->Fill(binieta,value);
         Occ_phi_L->Fill(iphi,value);
         Occ_map_L->Fill(binieta,iphi,value);
         Occ_rphi_L->Fill(r,phi,value);
           }
           
         else if (HFiter->id().depth()==2)
           {
         Occ_eta_S->Fill(binieta,value);
         Occ_phi_S->Fill(iphi,value);
         Occ_map_S->Fill(binieta,iphi,value);
         Occ_rphi_S->Fill(r,phi,value);
           }  
         HcalDetId id(HFiter->detid().rawId());
 
         HFtotalX+=HFiter->energy()*cos(PI*iphi/36.);
         HFtotalY+=HFiter->energy()*sin(PI*iphi/36.);
         HFtotalE+=HFiter->energy();
 
         int index=ieta+ETA_OFFSET_HF;
         if (index<0 || index>= HFETASIZE) continue;
         HF_weightedX[index]+=HFiter->energy()*cos(PI*iphi/36.);
         HF_weightedY[index]+=HFiter->energy()*sin(PI*iphi/36.);
         HF_energy[index]+=HFiter->energy();
         
       } // for (HFiter=hfHits.begin();...)
     
     // looped on all HF hits; calculate empty fraction
     //  empty towers  = # of cells with ET < 0.0625 GeV, or cells missing because of ZS
     //  Calculated as :  144 - (# of cells with ET >= 0.0625 GeV)
     //  At some point, allow for calculations when channels are masked (and less than 144 channels expected)
 
     // Check Ring 1
     double logvalue=-1;
     if (ring1totalchannels_>0)
       {
         if (emptytowersRing1>0)
           logvalue=-1.*log(emptytowersRing1/ring1totalchannels_);
         HFlumi_Occupancy_per_channel_vs_lumiblock_RING1->Fill(currentLS,logvalue);
         HFlumi_Occupancy_per_channel_vs_BX_RING1->Fill(bunchCrossing,logvalue);
       }
     // Check Ring 2
     logvalue=-1;
     if (ring2totalchannels_>0)
       {
         if (emptytowersRing2>0)
           logvalue=-1.*log(emptytowersRing2/ring2totalchannels_);
         HFlumi_Occupancy_per_channel_vs_lumiblock_RING2->Fill(currentLS,logvalue);
         HFlumi_Occupancy_per_channel_vs_BX_RING2->Fill(bunchCrossing,logvalue);
       }
 
     HFlumi_ETsum_vs_BX->Fill(bunchCrossing,pow(etx*etx+ety*ety,0.5));
     int hfeta=ETA_OFFSET_HF;
     for (int i=-1*hfeta;i<=hfeta;++i)
       {
         if (i==0) continue;
         if (i>-1*ETA_BOUND_HF && i <ETA_BOUND_HF) continue;
         int index = i + ETA_OFFSET_HF;
         if (index<0 || index>= HFETASIZE) continue;
         if (HF_energy[index]==0) continue;
         double moment=pow(HF_weightedX[index],2)+pow(HF_weightedY[index],2);
         moment=pow(moment,0.5);
         moment/=HF_energy[index];
         offset = (i>0 ? 0.5: -0.5);
         if (moment!=0)
           {
         if (makeDiagnostics_) HF_CenterOfEnergyRadius[index]->Fill(moment);
         COEradiusVSeta->Fill(i+offset,moment);
           }
       } // for (int i=-1*hfeta;i<=hfeta;++i)
     float ratiom,ratiop;
       
     for(int i=0;i<13;i++){
       for(int j=0;j<36;j++){
           
         if(hitsp[i][j][0]==hitsp[i][j][1]) continue;
           
         if (hitsp[i][j][0] < 1.2 && hitsp[i][j][1] < 1.8) continue;
         //use only lumi rings
         if (((i+29) < 33) || ((i+29) > 36)) continue;
         ratiop=fabs((fabs(hitsp[i][j][0])-fabs(hitsp[i][j][1]))/(fabs(hitsp[i][j][0])+fabs(hitsp[i][j][1])));
         //cout<<ratiop<<std::endl;
         if ((hitsp_Et[i][j][0] > 5. && hitsp[i][j][1] < 1.8) || (hitsp_Et[i][j][1] > 5. &&  hitsp[i][j][0] < 1.2)){
           Etsum_ratio_p->Fill(ratiop);
           if(abs(ratiop>0.95)) Etsum_ratio_map->Fill(i,2*j+1); // i=4,5,6,7 for HFlumi rings 
         }
       }
     }
       
     for(int p=0;p<13;p++){
       for(int q=0;q<36;q++){
           
         if(hitsm[p][q][0]==hitsm[p][q][1]) continue;
 
         if (hitsm[p][q][0] < 1.2 && hitsm[p][q][1] < 1.8) continue;
         //use only lumi rings
         if (((p+29) < 33) || ((p+29) > 36)) continue;
         ratiom=fabs((fabs(hitsm[p][q][0])-fabs(hitsm[p][q][1]))/(fabs(hitsm[p][q][0])+fabs(hitsm[p][q][1])));         
         if ((hitsm_Et[p][q][0] > 5. && hitsm[p][q][1] < 1.8) || (hitsm_Et[p][q][1] > 5. && hitsm[p][q][0] < 1.2)){
           Etsum_ratio_m->Fill(ratiom);
           if(abs(ratiom>0.95)) Etsum_ratio_map->Fill(7-p,2*q+1); // p=4,5,6,7 for HFlumi rings
           //p=7:  ieta=-36; p=4:  ieta=-33
         }
       }
     } 
       } // if (hfHits.size()>0)
   
     totalX=HBtotalX+HEtotalX+HOtotalX+HFtotalX;
     totalY=HBtotalY+HEtotalY+HOtotalY+HFtotalY;
     totalE=HBtotalE+HEtotalE+HOtotalE+HFtotalE;
 
     double moment;
     if (HBtotalE>0)
       {
     moment=pow(HBtotalX*HBtotalX+HBtotalY*HBtotalY,0.5)/HBtotalE;
     HBCenterOfEnergyRadius->Fill(moment);
     HBCenterOfEnergy->Fill(HBtotalX/HBtotalE, HBtotalY/HBtotalE);
       }
     if (HEtotalE>0)
       {
     moment=pow(HEtotalX*HEtotalX+HEtotalY*HEtotalY,0.5)/HEtotalE;
     HECenterOfEnergyRadius->Fill(moment);
     HECenterOfEnergy->Fill(HEtotalX/HEtotalE, HEtotalY/HEtotalE);
       }
     if (HOtotalE>0)
       {
     moment=pow(HOtotalX*HOtotalX+HOtotalY*HOtotalY,0.5)/HOtotalE;
     HOCenterOfEnergyRadius->Fill(moment);
     HOCenterOfEnergy->Fill(HOtotalX/HOtotalE, HOtotalY/HOtotalE);
       }
     if (HFtotalE>0)
       {
     moment=pow(HFtotalX*HFtotalX+HFtotalY*HFtotalY,0.5)/HFtotalE;
     HFCenterOfEnergyRadius->Fill(moment);
     HFCenterOfEnergy->Fill(HFtotalX/HFtotalE, HFtotalY/HFtotalE);
       }
     if (totalE>0)
       {
     moment = pow(totalX*totalX+totalY*totalY,0.5)/totalE;
     CenterOfEnergyRadius->Fill(moment);
     CenterOfEnergy->Fill(totalX/totalE, totalY/totalE);
       }
 
 
     
     for (HFDigiCollection::const_iterator j=hf.begin(); j!=hf.end(); j++){
       const HFDataFrame digi = (const HFDataFrame)(*j);
       //  calibs_= cond.getHcalCalibrations(digi.id());  // Old method was made private. 
       //       float en=0;
       //       float ts =0; float bs=0;
       //       int maxi=0; float maxa=0;
       //       for(int i=sigS0_; i<=sigS1_; i++){
       //    if(digi.sample(i).adc()>maxa){maxa=digi.sample(i).adc(); maxi=i;}
       //       }
       //       for(int i=sigS0_; i<=sigS1_; i++){     
       //    float tmp1 =0;   
       //         int j1=digi.sample(i).adc();
       //         tmp1 = (LedMonAdc2fc[j1]+0.5);       
       //    en += tmp1-calibs_.pedestal(digi.sample(i).capid());
       //    if(i>=(maxi-1) && i<=maxi+1){
       //      ts += i*(tmp1-calibs_.pedestal(digi.sample(i).capid()));
       //      bs += tmp1-calibs_.pedestal(digi.sample(i).capid());
       //    }
       //       }
 
       //---HFlumiplots
       int theTStobeused = 6;
       // will have masking later:
       int mask=1; 
       if(mask!=1) continue;
       //if we want to sum the 10 TS instead of just taking one:
       for (int i=0; i<digi.size(); i++) {
     if (i==theTStobeused) {
       float tmpET =0;
       int jadc=digi.sample(i).adc();
       //NOW LUT used in HLX are only identy LUTs, so Et filled
       //with unlinearised adc, ie tmpET = jadc
       //      tmpET = (adc2fc[jadc]+0.5);
       tmpET = jadc;
 
       //-find which wedge we are in
       //  ETsum and Occupancy will be summed for both L and S
       if(digi.id().ieta()>28){
         if((digi.id().iphi()==1)||(digi.id().iphi()==71)){
           HFlumi_ETsum_perwedge->Fill(1,tmpET);
               if((digi.id().ieta()==33)||(digi.id().ieta()==34)) {
         if(jadc>100) HFlumi_Occupancy_above_thr_r1->Fill(1,1);
         if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r1->Fill(1,1);
         if(jadc<10) HFlumi_Occupancy_below_thr_r1->Fill(1,1);
           }
           else if((digi.id().ieta()==35)||(digi.id().ieta()==36)) {
         if(jadc>100) HFlumi_Occupancy_above_thr_r2->Fill(1,1);
         if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r2->Fill(1,1);
         if(jadc<10) HFlumi_Occupancy_below_thr_r2->Fill(1,1);
           }
         }
         else {
           for (int iwedge=2; iwedge<19; iwedge++) {
         int itmp=4*(iwedge-1);
         if( (digi.id().iphi()==(itmp+1)) || (digi.id().iphi()==(itmp-1))) {
                   HFlumi_ETsum_perwedge->Fill(iwedge,tmpET);
           if((digi.id().ieta()==33)||(digi.id().ieta()==34)) {
             if(jadc>100) HFlumi_Occupancy_above_thr_r1->Fill(iwedge,1);
             if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r1->Fill(iwedge,1);
             if(jadc<10) HFlumi_Occupancy_below_thr_r1->Fill(iwedge,1);
           }
           else if((digi.id().ieta()==35)||(digi.id().ieta()==36)) {
             if(jadc>100) HFlumi_Occupancy_above_thr_r2->Fill(iwedge,1);
             if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r2->Fill(iwedge,1);
             if(jadc<10) HFlumi_Occupancy_below_thr_r2->Fill(iwedge,1);
           }
                   iwedge=99;
         }
           }
         }
       }  //--endif ieta in HF+
       else if(digi.id().ieta()<-28){
         if((digi.id().iphi()==1)||(digi.id().iphi()==71)){
           HFlumi_ETsum_perwedge->Fill(19,tmpET);
               if((digi.id().ieta()==-33)||(digi.id().ieta()==-34)) {
         if(jadc>100) HFlumi_Occupancy_above_thr_r1->Fill(19,1);
         if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r1->Fill(19,1);
         if(jadc<10) HFlumi_Occupancy_below_thr_r1->Fill(19,1);
           }
           else if((digi.id().ieta()==-35)||(digi.id().ieta()==-36)) {
         if(jadc>100) HFlumi_Occupancy_above_thr_r2->Fill(19,1);
         if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r2->Fill(19,1);
         if(jadc<10) HFlumi_Occupancy_below_thr_r2->Fill(19,1);
           }
         }
         else {
           for (int iw=2; iw<19; iw++) {
         int itemp=4*(iw-1);
         if( (digi.id().iphi()==(itemp+1)) || (digi.id().iphi()==(itemp-1))) {
                   HFlumi_ETsum_perwedge->Fill(iw+18,tmpET);
           if((digi.id().ieta()==-33)||(digi.id().ieta()==-34)) {
             if(jadc>100) HFlumi_Occupancy_above_thr_r1->Fill(iw+18,1);
             if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r1->Fill(iw+18,1);
             if(jadc<10) HFlumi_Occupancy_below_thr_r1->Fill(iw+18,1);
           }
           else if((digi.id().ieta()==-35)||(digi.id().ieta()==-36)) {
             if(jadc>100) HFlumi_Occupancy_above_thr_r2->Fill(iw+18,1);
             if((jadc>=10)&&(jadc<=100)) HFlumi_Occupancy_between_thrs_r2->Fill(iw+18,1);
             if(jadc<10) HFlumi_Occupancy_below_thr_r2->Fill(iw+18,1);
           }
                   iw=99;
         }
           }
         }
       }//---endif ieta inHF-
     }//---endif TS=nr6
       } 
     }//------end loop over TS for lumi
     return;
   }
 }

void HcalBeamMonitor::reset ( void )

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 84 of file HcalBeamMonitor.cc.

References CenterOfEnergy, CenterOfEnergyRadius, COEradiusVSeta, Energy_Occ, Etsum_eta_L, Etsum_eta_S, Etsum_map_L, Etsum_map_S, Etsum_phi_L, Etsum_phi_S, Etsum_ratio_m, Etsum_ratio_map, Etsum_ratio_p, Etsum_rphi_L, Etsum_rphi_S, HBCenterOfEnergy, HBCenterOfEnergyRadius, HECenterOfEnergy, HECenterOfEnergyRadius, HFCenterOfEnergy, HFCenterOfEnergyRadius, HFlumi_diag_deadcells, HFlumi_diag_hotcells, HFlumi_Et_per_channel_vs_lumiblock, HFlumi_ETsum_perwedge, HFlumi_ETsum_vs_BX, HFlumi_occ_LS, HFlumi_Occupancy_above_thr_r1, HFlumi_Occupancy_above_thr_r2, HFlumi_Occupancy_below_thr_r1, HFlumi_Occupancy_below_thr_r2, HFlumi_Occupancy_between_thrs_r1, HFlumi_Occupancy_between_thrs_r2, HFlumi_Occupancy_per_channel_vs_BX_RING1, HFlumi_Occupancy_per_channel_vs_BX_RING2, HFlumi_Occupancy_per_channel_vs_lumiblock_RING1, HFlumi_Occupancy_per_channel_vs_lumiblock_RING2, HFlumi_Ring1Status_vs_LS, HFlumi_Ring2Status_vs_LS, HFlumi_total_deadcells, HFlumi_total_hotcells, HOCenterOfEnergy, HOCenterOfEnergyRadius, Occ_eta_L, Occ_eta_S, Occ_map_L, Occ_map_S, Occ_phi_L, Occ_phi_S, Occ_rphi_L, Occ_rphi_S, and MonitorElement::Reset().

Referenced by beginRun().

 {
   CenterOfEnergyRadius->Reset();
   CenterOfEnergy->Reset();
   COEradiusVSeta->Reset();
 
   HBCenterOfEnergyRadius->Reset();
   HBCenterOfEnergy->Reset();
   HECenterOfEnergyRadius->Reset();
   HECenterOfEnergy->Reset();
   HOCenterOfEnergyRadius->Reset();
   HOCenterOfEnergy->Reset();
   HFCenterOfEnergyRadius->Reset();
   HFCenterOfEnergy->Reset();
 
   Etsum_eta_L->Reset();
   Etsum_eta_S->Reset();
   Etsum_phi_L->Reset();
   Etsum_phi_S->Reset();
   Etsum_ratio_p->Reset();
   Etsum_ratio_m->Reset();
   Etsum_map_L->Reset();
   Etsum_map_S->Reset();
   Etsum_ratio_map->Reset();
   Etsum_rphi_L->Reset();
   Etsum_rphi_S->Reset();
   Energy_Occ->Reset();
 
   Occ_rphi_L->Reset();
   Occ_rphi_S->Reset();
   Occ_eta_L->Reset();
   Occ_eta_S->Reset();
   Occ_phi_L->Reset();
   Occ_phi_S->Reset();
   Occ_map_L->Reset();
   Occ_map_S->Reset();
   
   HFlumi_ETsum_perwedge->Reset();
   HFlumi_Occupancy_above_thr_r1->Reset();
   HFlumi_Occupancy_between_thrs_r1->Reset();
   HFlumi_Occupancy_below_thr_r1->Reset();
   HFlumi_Occupancy_above_thr_r2->Reset();
   HFlumi_Occupancy_between_thrs_r2->Reset();
   HFlumi_Occupancy_below_thr_r2->Reset();
 
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING1->Reset();
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING2->Reset();
   HFlumi_Occupancy_per_channel_vs_BX_RING1->Reset();
   HFlumi_Occupancy_per_channel_vs_BX_RING2->Reset();
   HFlumi_ETsum_vs_BX->Reset();
   HFlumi_Et_per_channel_vs_lumiblock->Reset();
 
   HFlumi_occ_LS->Reset();
   HFlumi_total_hotcells->Reset();
   HFlumi_total_deadcells->Reset();
   HFlumi_diag_hotcells->Reset();
   HFlumi_diag_deadcells->Reset();
 
 
   HFlumi_Ring1Status_vs_LS->Reset();
   HFlumi_Ring2Status_vs_LS->Reset();
 }

void HcalBeamMonitor::SetEtaLabels ( MonitorElement * h )

private

Definition at line 1307 of file HcalBeamMonitor.cc.

References MonitorElement::getTH2F().

Referenced by setup().

 {
   h->getTH2F()->GetXaxis()->SetBinLabel(1,"-36S");
   h->getTH2F()->GetXaxis()->SetBinLabel(2,"-35S");
   h->getTH2F()->GetXaxis()->SetBinLabel(3,"-34L");
   h->getTH2F()->GetXaxis()->SetBinLabel(4,"-33L");
   h->getTH2F()->GetXaxis()->SetBinLabel(5,"33L");
   h->getTH2F()->GetXaxis()->SetBinLabel(6,"34L");
   h->getTH2F()->GetXaxis()->SetBinLabel(7,"35S");
   h->getTH2F()->GetXaxis()->SetBinLabel(8,"36S");
   return;
 }

void HcalBeamMonitor::setup ( void )

virtual

Reimplemented from HcalBaseDQMonitor.

Definition at line 159 of file HcalBeamMonitor.cc.

References funct::abs(), DQMStore::book1D(), DQMStore::book2D(), DQMStore::bookProfile(), CenterOfEnergy, CenterOfEnergyRadius, COEradiusVSeta, gather_cfg::cout, HcalBaseDQMonitor::dbe_, HcalBaseDQMonitor::debug_, Energy_Occ, ETA_BOUND_HE, ETA_BOUND_HF, ETA_OFFSET_HB, ETA_OFFSET_HE, ETA_OFFSET_HF, ETA_OFFSET_HO, Etsum_eta_L, Etsum_eta_S, Etsum_map_L, Etsum_map_S, Etsum_phi_L, Etsum_phi_S, Etsum_ratio_m, Etsum_ratio_map, Etsum_ratio_p, Etsum_rphi_L, Etsum_rphi_S, MonitorElement::getTH1F(), MonitorElement::getTProfile(), HB_CenterOfEnergyRadius, HBCenterOfEnergy, HBCenterOfEnergyRadius, HE_CenterOfEnergyRadius, HECenterOfEnergy, HECenterOfEnergyRadius, HF_CenterOfEnergyRadius, HFCenterOfEnergy, HFCenterOfEnergyRadius, HFlumi_diag_deadcells, HFlumi_diag_hotcells, HFlumi_Et_per_channel_vs_lumiblock, HFlumi_ETsum_perwedge, HFlumi_ETsum_vs_BX, HFlumi_occ_LS, HFlumi_Occupancy_above_thr_r1, HFlumi_Occupancy_above_thr_r2, HFlumi_Occupancy_below_thr_r1, HFlumi_Occupancy_below_thr_r2, HFlumi_Occupancy_between_thrs_r1, HFlumi_Occupancy_between_thrs_r2, HFlumi_Occupancy_per_channel_vs_BX_RING1, HFlumi_Occupancy_per_channel_vs_BX_RING2, HFlumi_Occupancy_per_channel_vs_lumiblock_RING1, HFlumi_Occupancy_per_channel_vs_lumiblock_RING2, HFlumi_Ring1Status_vs_LS, HFlumi_Ring2Status_vs_LS, HFlumi_total_deadcells, HFlumi_total_hotcells, HO_CenterOfEnergyRadius, HOCenterOfEnergy, HOCenterOfEnergyRadius, i, HcalBaseDQMonitor::makeDiagnostics_, HcalBaseDQMonitor::NLumiBlocks_, Occ_eta_L, Occ_eta_S, Occ_map_L, Occ_map_S, Occ_phi_L, Occ_phi_S, Occ_rphi_L, Occ_rphi_S, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::setCurrentFolder(), SetEtaLabels(), HcalBaseDQMonitor::setup(), setupDone_, and HcalBaseDQMonitor::subdir_.

Referenced by beginRun().

 {
   if (setupDone_)
     return;
   setupDone_ = true;
    if (debug_>0) std::cout <<"<HcalBeamMonitor::setup> Setup in progress..."<<std::endl;
   HcalBaseDQMonitor::setup();
   if (!dbe_) return;
 
   //jason's
   dbe_->setCurrentFolder(subdir_);
   CenterOfEnergyRadius = dbe_->book1D("CenterOfEnergyRadius",
                        "Center Of Energy radius",
                        200,0,1);
       
   CenterOfEnergyRadius->setAxisTitle("(normalized) radius",1);
       
   CenterOfEnergy = dbe_->book2D("CenterOfEnergy",
                  "Center of Energy;normalized x coordinate;normalize y coordinate",
                  40,-1,1,
                  40,-1,1);
 
   COEradiusVSeta = dbe_->bookProfile("COEradiusVSeta",
                       "Center of Energy radius vs i#eta",
                       172,-43,43,
                       20,0,1);
   COEradiusVSeta->setAxisTitle("i#eta",1);
   COEradiusVSeta->setAxisTitle("(normalized) radius",2);
       
   std::stringstream histname;
   std::stringstream histtitle;
   dbe_->setCurrentFolder(subdir_+"HB");
   HBCenterOfEnergyRadius = dbe_->book1D("HBCenterOfEnergyRadius",
                      "HB Center Of Energy radius",
                      200,0,1);
   HBCenterOfEnergy = dbe_->book2D("HBCenterOfEnergy",
                    "HB Center of Energy",
                    40,-1,1,
                    40,-1,1);
   if (makeDiagnostics_)
     {
       for (int i=-16;i<=16;++i)
     {
       if (i==0) continue;
       histname.str("");
       histtitle.str("");
       histname<<"HB_CenterOfEnergyRadius_ieta"<<i;
       histtitle<<"HB Center Of Energy ieta = "<<i;
       HB_CenterOfEnergyRadius[i+ETA_OFFSET_HB]=dbe_->book1D(histname.str().c_str(),
                                  histtitle.str().c_str(),
                                  200,0,1);
     } // end of HB loop
     }
   dbe_->setCurrentFolder(subdir_+"HE");
   HECenterOfEnergyRadius = dbe_->book1D("HECenterOfEnergyRadius",
                      "HE Center Of Energy radius",
                      200,0,1);
   HECenterOfEnergy = dbe_->book2D("HECenterOfEnergy",
                    "HE Center of Energy",
                    40,-1,1,
                    40,-1,1);
 
   if (makeDiagnostics_)
     {
       for (int i=-29;i<=29;++i)
     {
       if (abs(i)<ETA_BOUND_HE) continue;
       histname.str("");
       histtitle.str("");
       histname<<"HE_CenterOfEnergyRadius_ieta"<<i;
       histtitle<<"HE Center Of Energy ieta = "<<i;
       HE_CenterOfEnergyRadius[i+ETA_OFFSET_HE]=dbe_->book1D(histname.str().c_str(),
                                  histtitle.str().c_str(),
                                  200,0,1);
     } // end of HE loop
     }
   dbe_->setCurrentFolder(subdir_+"HO");
   HOCenterOfEnergyRadius = dbe_->book1D("HOCenterOfEnergyRadius",
                      "HO Center Of Energy radius",
                      200,0,1);
   HOCenterOfEnergy = dbe_->book2D("HOCenterOfEnergy",
                    "HO Center of Energy",
                    40,-1,1,
                    40,-1,1);
   if (makeDiagnostics_)
     {
       for (int i=-15;i<=15;++i)
     {
       if (i==0) continue;
       histname.str("");
       histtitle.str("");
       histname<<"HO_CenterOfEnergyRadius_ieta"<<i;
       histtitle<<"HO Center Of Energy radius ieta = "<<i;
       HO_CenterOfEnergyRadius[i+ETA_OFFSET_HO]=dbe_->book1D(histname.str().c_str(),
                                  histtitle.str().c_str(),
                                  200,0,1);
     } // end of HO loop
     }
   dbe_->setCurrentFolder(subdir_+"HF");
   HFCenterOfEnergyRadius = dbe_->book1D("HFCenterOfEnergyRadius",
                      "HF Center Of Energy radius",
                      200,0,1);
   HFCenterOfEnergy = dbe_->book2D("HFCenterOfEnergy",
                    "HF Center of Energy",
                    40,-1,1,
                    40,-1,1);
   if (makeDiagnostics_)
     {
       for (int i=-41;i<=41;++i)
     {
       if (abs(i)<ETA_BOUND_HF) continue;
       histname.str("");
       histtitle.str("");
       histname<<"HF_CenterOfEnergyRadius_ieta"<<i;
       histtitle<<"HF Center Of Energy radius ieta = "<<i;
       HF_CenterOfEnergyRadius[i+ETA_OFFSET_HF]=dbe_->book1D(histname.str().c_str(),
                                  histtitle.str().c_str(),
                                  200,0,1);
     } // end of HF loop
     }
       
   dbe_->setCurrentFolder(subdir_+"Lumi");
   // Wenhan's 
   // reducing bins from ",200,0,2000" to ",40,0,800"
       
   float radiusbins[13]={169,201,240,286,340,406,483,576,686,818,975,1162,1300};
   float phibins[71]={-3.5,-3.4,-3.3,-3.2,-3.1,
              -3.0,-2.9,-2.8,-2.7,-2.6,-2.5,-2.4,-2.3,-2.2,-2.1,
              -2.0,-1.9,-1.8,-1.7,-1.6,-1.5,-1.4,-1.3,-1.2,-1.1,
              -1.0,-0.9,-0.8,-0.7,-0.6,-0.5,-0.4,-0.3,-0.2,-0.1,
              0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9,
              1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9,
              2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9,
              3.0, 3.1, 3.2, 3.3, 3.4, 3.5};
   Etsum_eta_L=dbe_->bookProfile("Et Sum vs Eta Long Fiber","Et Sum per Area vs Eta Long Fiber",27,0,27,100,0,100);
   Etsum_eta_S=dbe_->bookProfile("Et Sum vs Eta Short Fiber","Et Sum per Area vs Eta Short Fiber",27,0,27,100,0,100);
   Etsum_phi_L=dbe_->bookProfile("Et Sum vs Phi Long Fiber","Et Sum per Area vs Phi Long Fiber",36,0.5,72.5,100,0,100);
   Etsum_phi_S=dbe_->bookProfile("Et Sum vs Phi Short Fiber","Et Sum per Area crossing vs Phi Short Fiber",36,0.5,72.5,100,0,100);
 
   Etsum_ratio_p=dbe_->book1D("Occ vs PMT events HF+","Energy difference of Long and Short Fiber HF+ in PMT events",105,0.,1.05);
   Energy_Occ=dbe_->book1D("Occ vs Energy","Occupancy vs Energy",200,0,2000);
   Etsum_ratio_m=dbe_->book1D("Occ vs PMT events HF-","Energy difference of Long and Short Fiber HF- in PMT events",105,0.,1.05);
   Etsum_map_L=dbe_->book2D("EtSum 2D phi and eta Long Fiber","Et Sum 2D phi and eta Long Fiber",27,0,27,36,0.5,72.5);
   Etsum_map_S=dbe_->book2D("EtSum 2D phi and eta Short Fiber","Et Sum 2D phi and eta Short Fiber",27,0,27,36,0.5,72.5);
 
   Etsum_rphi_S=dbe_->book2D("EtSum 2D phi and radius Short Fiber","Et Sum 2D phi and radius Short Fiber",12, radiusbins, 70, phibins);
   Etsum_rphi_L=dbe_->book2D("EtSum 2D phi and radius Long Fiber","Et Sum 2D phi and radius Long Fiber",12, radiusbins, 70, phibins);
 
   Etsum_ratio_map=dbe_->book2D("Abnormal PMT events","Abnormal PMT events",
                 8,0,8,36, 0.5,72.5);
   SetEtaLabels(Etsum_ratio_map);
 
   HFlumi_occ_LS = dbe_->book2D("HFlumi_occ_LS","HFlumi occupancy for current LS",
                 8,0,8,36, 0.5,72.5);
   SetEtaLabels(HFlumi_occ_LS);
       
   HFlumi_total_deadcells = dbe_->book2D("HFlumi_total_deadcells","Number of dead lumi channels for LS with at least 10 bad channels",
                      8,0,8,36,0.5,72.5);
   SetEtaLabels(HFlumi_total_deadcells);
   HFlumi_total_hotcells = dbe_->book2D("HFlumi_total_hotcells","Number of hot lumi channels for LS with at least 10 bad channels",
                     8,0,8,36,0.5,72.5);
   SetEtaLabels(HFlumi_total_hotcells);
 
   HFlumi_diag_deadcells = dbe_->book2D("HFlumi_diag_deadcells","Channels that had no hit for at least one LS",
                        8,0,8,36,0.5,72.5);
   SetEtaLabels(HFlumi_diag_deadcells);
   HFlumi_diag_hotcells = dbe_->book2D("HFlumi_diag_hotcells","Channels that appeared hot for at least one LS",
                       8,0,8,36,0.5,72.5);
   SetEtaLabels(HFlumi_diag_hotcells);
 
 
 
   Occ_rphi_S=dbe_->book2D("Occ 2D phi and radius Short Fiber","Occupancy 2D phi and radius Short Fiber",12, radiusbins, 70, phibins);
   Occ_rphi_L=dbe_->book2D("Occ 2D phi and radius Long Fiber","Occupancy 2D phi and radius Long Fiber",12, radiusbins, 70, phibins);
   Occ_eta_S=dbe_->bookProfile("Occ vs iEta Short Fiber","Occ per Bunch crossing vs iEta Short Fiber",27,0,27,40,0,800);
   Occ_eta_L=dbe_->bookProfile("Occ vs iEta Long Fiber","Occ per Bunch crossing vs iEta Long Fiber",27,0,27,40,0,800);
       
   Occ_phi_L=dbe_->bookProfile("Occ vs iPhi Long Fiber","Occ per Bunch crossing vs iPhi Long Fiber",36,0.5,72.5,40,0,800);
       
   Occ_phi_S=dbe_->bookProfile("Occ vs iPhi Short Fiber","Occ per Bunch crossing vs iPhi Short Fiber",36,0.5,72.5,40,0,800);
       
   Occ_map_L=dbe_->book2D("Occ_map Long Fiber","Occ Map long Fiber (above threshold)",27,0,27,36,0.5,72.5);
   Occ_map_S=dbe_->book2D("Occ_map Short Fiber","Occ Map Short Fiber (above threshold)",27,0,27,36,0.5,72.5);
 
   std::stringstream binlabel;
   for (int zz=0;zz<27;++zz)
     {
       if (zz<13)
     binlabel<<zz-41;
       else if (zz==13)
     binlabel<<"NULL";
       else
     binlabel<<zz+15;
       Occ_eta_S->setBinLabel(zz+1,binlabel.str().c_str());
       Occ_eta_L->setBinLabel(zz+1,binlabel.str().c_str());
       Occ_map_S->setBinLabel(zz+1,binlabel.str().c_str());
       Occ_map_L->setBinLabel(zz+1,binlabel.str().c_str());
       Etsum_eta_S->setBinLabel(zz+1,binlabel.str().c_str());
       Etsum_eta_L->setBinLabel(zz+1,binlabel.str().c_str());
       Etsum_map_S->setBinLabel(zz+1,binlabel.str().c_str());
       Etsum_map_L->setBinLabel(zz+1,binlabel.str().c_str());
       binlabel.str("");
     }
 
   //HFlumi plots
   HFlumi_ETsum_perwedge =  dbe_->book1D("HF lumi ET-sum per wedge","HF lumi ET-sum per wedge;wedge",36,1,37);
   HFlumi_ETsum_perwedge->getTH1F()->SetMinimum(0); 
       
   HFlumi_Occupancy_above_thr_r1 =  dbe_->book1D("HF lumi Occupancy above threshold ring1","HF lumi Occupancy above threshold ring1;wedge",36,1,37);
   HFlumi_Occupancy_between_thrs_r1 = dbe_->book1D("HF lumi Occupancy between thresholds ring1","HF lumi Occupancy between thresholds ring1;wedge",36,1,37);
   HFlumi_Occupancy_below_thr_r1 = dbe_->book1D("HF lumi Occupancy below threshold ring1","HF lumi Occupancy below threshold ring1;wedge",36,1,37);
   HFlumi_Occupancy_above_thr_r2 = dbe_->book1D("HF lumi Occupancy above threshold ring2","HF lumi Occupancy above threshold ring2;wedge",36,1,37);
   HFlumi_Occupancy_between_thrs_r2 = dbe_->book1D("HF lumi Occupancy between thresholds ring2","HF lumi Occupancy between thresholds ring2;wedge",36,1,37);
   HFlumi_Occupancy_below_thr_r2 = dbe_->book1D("HF lumi Occupancy below threshold ring2","HF lumi Occupancy below threshold ring2;wedge",36,1,37);
 
   HFlumi_Occupancy_above_thr_r1->getTH1F()->SetMinimum(0);
   HFlumi_Occupancy_between_thrs_r1->getTH1F()->SetMinimum(0);
   HFlumi_Occupancy_below_thr_r1->getTH1F()->SetMinimum(0);
   HFlumi_Occupancy_above_thr_r2->getTH1F()->SetMinimum(0);
   HFlumi_Occupancy_between_thrs_r2->getTH1F()->SetMinimum(0);
   HFlumi_Occupancy_below_thr_r2->getTH1F()->SetMinimum(0);
  
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING1 = dbe_->bookProfile("HFlumiRing1OccupancyPerChannelVsLB",
                                       "HFlumi Occupancy per channel vs lumi-block (RING 1);LS; -ln(empty fraction)",
                                       NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING2 = dbe_->bookProfile("HFlumiRing2OccupancyPerChannelVsLB","HFlumi Occupancy per channel vs lumi-block (RING 2);LS; -ln(empty fraction)",NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
 
   HFlumi_Occupancy_per_channel_vs_BX_RING1 = dbe_->bookProfile("HFlumi Occupancy per channel vs BX (RING 1)","HFlumi Occupancy per channel vs BX (RING 1);BX; -ln(empty fraction)",4000,0,4000,100,0,10000);
   HFlumi_Occupancy_per_channel_vs_BX_RING2 = dbe_->bookProfile("HFlumi Occupancy per channel vs BX (RING 2)","HFlumi Occupancy per channel vs BX (RING 2);BX; -ln(empty fraction)",4000,0,4000,100,0,10000);
   HFlumi_ETsum_vs_BX = dbe_->bookProfile("HFlumi_ETsum_vs_BX","HFlumi ETsum vs BX; BX; ETsum",4000,0,4000,100,0,10000);
 
   HFlumi_Et_per_channel_vs_lumiblock = dbe_->bookProfile("HFlumi Et per channel vs lumi-block","HFlumi Et per channel vs lumi-block;LS;ET",NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
 
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING1->getTProfile()->SetMarkerStyle(20);
   HFlumi_Occupancy_per_channel_vs_lumiblock_RING2->getTProfile()->SetMarkerStyle(20);
   HFlumi_Et_per_channel_vs_lumiblock->getTProfile()->SetMarkerStyle(20);
 
   HFlumi_Ring1Status_vs_LS = dbe_->bookProfile("HFlumi_Ring1Status_vs_LS","Fraction of good Ring 1 channels vs LS;LS; Fraction of Good Channels",NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
   HFlumi_Ring2Status_vs_LS = dbe_->bookProfile("HFlumi_Ring2Status_vs_LS","Fraction of good Ring 2 channels vs LS;LS; Fraction of Good Channels",NLumiBlocks_,0.5,NLumiBlocks_+0.5,100,0,10000);
   HFlumi_Ring1Status_vs_LS->getTProfile()->SetMarkerStyle(20);
   HFlumi_Ring2Status_vs_LS->getTProfile()->SetMarkerStyle(20);
 
   return;
 }