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CSCOfflineMonitor Class Reference

#include <CSCOfflineMonitor.h>

Inheritance diagram for CSCOfflineMonitor:
edm::EDAnalyzer edm::EDConsumerBase

Public Types

enum  AxisType { X =1, Y =2, Z =3 }
 
enum  LabelType { SMALL, EXTENDED }
 
- Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer ModuleType
 

Public Member Functions

void analyze (const edm::Event &event, const edm::EventSetup &eventSetup)
 
virtual void beginRun (edm::Run const &, edm::EventSetup const &)
 
void bookTheHists ()
 
 CSCOfflineMonitor (const edm::ParameterSet &pset)
 
virtual void endJob ()
 
virtual void endRun (edm::Run const &, edm::EventSetup const &)
 
void finalize ()
 
virtual ~CSCOfflineMonitor ()
 
- 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 applyCSClabels (MonitorElement *meHisto, LabelType t, AxisType a)
 
int chamberSerial (CSCDetId id)
 
void doBXMonitor (edm::Handle< CSCALCTDigiCollection > alcts, edm::Handle< CSCCLCTDigiCollection > clcts, const edm::Event &event, const edm::EventSetup &eventSetup)
 
void doEfficiencies (edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
 
void doOccupancies (edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::Handle< CSCCLCTDigiCollection > clcts)
 
void doPedestalNoise (edm::Handle< CSCStripDigiCollection > strips)
 
void doRecHits (edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCStripDigiCollection > strips, edm::ESHandle< CSCGeometry > cscGeom)
 
void doResolution (edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
 
void doSegments (edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
 
void doStripDigis (edm::Handle< CSCStripDigiCollection > strips)
 
void doWireDigis (edm::Handle< CSCWireDigiCollection > wires)
 
double extrapolate1D (double initPosition, double initDirection, double parameterOfTheLine)
 
void fillEfficiencyHistos (int bin, int flag)
 
float fitX (const CLHEP::HepMatrix &sp, const CLHEP::HepMatrix &ep)
 
void getEfficiency (float bin, float Norm, std::vector< float > &eff)
 
float getSignal (const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
 
void harvestChamberMeans (MonitorElement *meMean1D, MonitorElement *meMean2D, MonitorElement *hNum, MonitorElement *meDenom)
 
void histoEfficiency (TH1F *readHisto, MonitorElement *writeHisto)
 
double lineParametrization (double z1Position, double z2Position, double z1Direction)
 
void normalize (MonitorElement *me)
 
int typeIndex (CSCDetId id, int flag=1)
 
bool withinSensitiveRegion (LocalPoint localPos, const std::array< const float, 4 > &layerBounds, int station, int ring, float shiftFromEdge, float shiftFromDeadZone)
 

Private Attributes

edm::EDGetTokenT
< CSCALCTDigiCollection
al_token
 
edm::EDGetTokenT
< CSCCLCTDigiCollection
cl_token
 
DQMStoredbe
 
bool finalizedHistograms_
 
MonitorElementhALCTgetBX
 
MonitorElementhALCTgetBX2Denominator
 
MonitorElementhALCTgetBX2DMeans
 
MonitorElementhALCTgetBX2DNumerator
 
MonitorElementhALCTgetBXChamberMeans
 
MonitorElementhALCTgetBXSerial
 
MonitorElementhALCTMatch
 
MonitorElementhALCTMatch2Denominator
 
MonitorElementhALCTMatch2DMeans
 
MonitorElementhALCTMatch2DNumerator
 
MonitorElementhALCTMatchChamberMeans
 
MonitorElementhALCTMatchSerial
 
MonitorElementhCLCTL1A
 
MonitorElementhCLCTL1A2Denominator
 
MonitorElementhCLCTL1A2DMeans
 
MonitorElementhCLCTL1A2DNumerator
 
MonitorElementhCLCTL1AChamberMeans
 
MonitorElementhCLCTL1ASerial
 
MonitorElementhCSCOccupancy
 
MonitorElementhEffDenominator
 
MonitorElementhORecHits
 
MonitorElementhORecHitsSerial
 
MonitorElementhOSegments
 
MonitorElementhOSegmentsSerial
 
MonitorElementhOStrips
 
MonitorElementhOStripsAndWiresAndCLCT
 
MonitorElementhOStripSerial
 
MonitorElementhOWires
 
MonitorElementhOWiresAndCLCT
 
MonitorElementhOWireSerial
 
MonitorElementhRHEff
 
MonitorElementhRHEff2
 
std::vector< MonitorElement * > hRHGlobal
 
MonitorElementhRHnrechits
 
std::vector< MonitorElement * > hRHRatioQ
 
MonitorElementhRHSTE
 
MonitorElementhRHSTE2
 
std::vector< MonitorElement * > hRHsterr
 
std::vector< MonitorElement * > hRHstpos
 
std::vector< MonitorElement * > hRHSumQ
 
std::vector< MonitorElement * > hRHTiming
 
std::vector< MonitorElement * > hRHTimingAnode
 
std::vector< MonitorElement * > hSChiSq
 
MonitorElementhSChiSqAll
 
std::vector< MonitorElement * > hSChiSqProb
 
MonitorElementhSChiSqProbAll
 
MonitorElementhSEff
 
MonitorElementhSEff2
 
MonitorElementhSensitiveAreaEvt
 
MonitorElementhSGlobalPhi
 
MonitorElementhSGlobalTheta
 
std::vector< MonitorElement * > hSnhits
 
MonitorElementhSnhitsAll
 
MonitorElementhSnSegments
 
std::vector< MonitorElement * > hSResid
 
MonitorElementhSSTE
 
MonitorElementhSSTE2
 
MonitorElementhSTimeCathode
 
MonitorElementhSTimeCombined
 
MonitorElementhSTimeVsTOF
 
MonitorElementhSTimeVsZ
 
MonitorElementhStripEff2
 
MonitorElementhStripNFired
 
std::vector< MonitorElement * > hStripNumber
 
std::vector< MonitorElement * > hStripPed
 
MonitorElementhStripReadoutEff2
 
MonitorElementhStripSTE2
 
MonitorElementhWireEff2
 
MonitorElementhWirenGroupsTotal
 
std::vector< MonitorElement * > hWireNumber
 
MonitorElementhWireSTE2
 
std::vector< MonitorElement * > hWireTBin
 
edm::ParameterSet param
 
edm::EDGetTokenT
< FEDRawDataCollection
rd_token
 
edm::EDGetTokenT
< CSCRecHit2DCollection
rh_token
 
edm::EDGetTokenT
< CSCStripDigiCollection
sd_token
 
edm::EDGetTokenT
< CSCSegmentCollection
se_token
 
edm::EDGetTokenT
< CSCWireDigiCollection
wd_token
 

Additional Inherited Members

- 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 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)
 

Detailed Description

Simple package for offline CSC DQM based on RecoLocalMuon/CSCValidation: digis, rechits, segments

Andrew Kubik, Northwestern University, Oct 2008

Definition at line 70 of file CSCOfflineMonitor.h.

Member Enumeration Documentation

Enumerator
X 
Y 
Z 

Definition at line 85 of file CSCOfflineMonitor.h.

Enumerator
SMALL 
EXTENDED 

Definition at line 84 of file CSCOfflineMonitor.h.

Constructor & Destructor Documentation

CSCOfflineMonitor::CSCOfflineMonitor ( const edm::ParameterSet pset)

Definition at line 15 of file CSCOfflineMonitor.cc.

References al_token, cl_token, finalizedHistograms_, edm::ParameterSet::getParameter(), param, rd_token, rh_token, sd_token, se_token, and wd_token.

15  :
16  dbe(nullptr)
17 {
18 
19  param = pset;
20 
21  rd_token = consumes<FEDRawDataCollection>( pset.getParameter<edm::InputTag>("FEDRawDataCollectionTag") );
22  sd_token = consumes<CSCStripDigiCollection>( pset.getParameter<edm::InputTag>("stripDigiTag") );
23  wd_token = consumes<CSCWireDigiCollection>( pset.getParameter<edm::InputTag>("wireDigiTag") );
24  al_token = consumes<CSCALCTDigiCollection>( pset.getParameter<edm::InputTag>("alctDigiTag") );
25  cl_token = consumes<CSCCLCTDigiCollection>( pset.getParameter<edm::InputTag>("clctDigiTag") );
26  rh_token = consumes<CSCRecHit2DCollection>( pset.getParameter<edm::InputTag>("cscRecHitTag") );
27  se_token = consumes<CSCSegmentCollection>( pset.getParameter<edm::InputTag>("cscSegTag") );
28 
30 
31 }
edm::EDGetTokenT< CSCALCTDigiCollection > al_token
T getParameter(std::string const &) const
edm::EDGetTokenT< CSCWireDigiCollection > wd_token
edm::ParameterSet param
edm::EDGetTokenT< FEDRawDataCollection > rd_token
edm::EDGetTokenT< CSCCLCTDigiCollection > cl_token
edm::EDGetTokenT< CSCSegmentCollection > se_token
edm::EDGetTokenT< CSCStripDigiCollection > sd_token
edm::EDGetTokenT< CSCRecHit2DCollection > rh_token
virtual CSCOfflineMonitor::~CSCOfflineMonitor ( )
inlinevirtual

Definition at line 74 of file CSCOfflineMonitor.h.

74 { };

Member Function Documentation

void CSCOfflineMonitor::analyze ( const edm::Event event,
const edm::EventSetup eventSetup 
)
virtual

Implements edm::EDAnalyzer.

Definition at line 601 of file CSCOfflineMonitor.cc.

References al_token, cl_token, cscSegments_cfi::cscSegments, doBXMonitor(), doEfficiencies(), doOccupancies(), doPedestalNoise(), doRecHits(), doResolution(), doSegments(), doStripDigis(), doWireDigis(), edm::EventSetup::get(), rh_token, sd_token, se_token, RecoTauPiZeroBuilderPlugins_cfi::strips, and wd_token.

601  {
602 
607  event.getByToken( sd_token, strips );
608  event.getByToken( wd_token, wires );
609  event.getByToken( al_token, alcts );
610  event.getByToken( cl_token, clcts );
611 
612  // Get the CSC Geometry :
614  eventSetup.get<MuonGeometryRecord>().get(cscGeom);
615 
616  // Get the RecHits collection :
618  event.getByToken( rh_token, recHits );
619 
620  // get CSC segment collection
622  event.getByToken( se_token, cscSegments );
623 
624  doOccupancies(strips,wires,recHits,cscSegments,clcts);
625  doStripDigis(strips);
626  doWireDigis(wires);
627  doRecHits(recHits,strips,cscGeom);
628  doSegments(cscSegments,cscGeom);
629  doResolution(cscSegments,cscGeom);
630  doPedestalNoise(strips);
631  doEfficiencies(wires,strips, recHits, cscSegments,cscGeom);
632  doBXMonitor(alcts, clcts, event, eventSetup);
633 }
edm::EDGetTokenT< CSCALCTDigiCollection > al_token
void doPedestalNoise(edm::Handle< CSCStripDigiCollection > strips)
void doResolution(edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
edm::EDGetTokenT< CSCWireDigiCollection > wd_token
edm::EDGetTokenT< CSCCLCTDigiCollection > cl_token
edm::EDGetTokenT< CSCSegmentCollection > se_token
edm::EDGetTokenT< CSCStripDigiCollection > sd_token
void doSegments(edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
void doWireDigis(edm::Handle< CSCWireDigiCollection > wires)
const T & get() const
Definition: EventSetup.h:55
void doBXMonitor(edm::Handle< CSCALCTDigiCollection > alcts, edm::Handle< CSCCLCTDigiCollection > clcts, const edm::Event &event, const edm::EventSetup &eventSetup)
void doStripDigis(edm::Handle< CSCStripDigiCollection > strips)
edm::EDGetTokenT< CSCRecHit2DCollection > rh_token
void doEfficiencies(edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
void doOccupancies(edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::Handle< CSCCLCTDigiCollection > clcts)
void doRecHits(edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCStripDigiCollection > strips, edm::ESHandle< CSCGeometry > cscGeom)
void CSCOfflineMonitor::applyCSClabels ( MonitorElement meHisto,
LabelType  t,
AxisType  a 
)
private

Definition at line 1916 of file CSCOfflineMonitor.cc.

References EXTENDED, NULL, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), and SMALL.

Referenced by bookTheHists().

1916  {
1917  if (me != NULL)
1918  {
1919  me->setAxisTitle("Chamber #");
1920  if (t == EXTENDED)
1921  {
1922  me->setBinLabel(1,"ME -4/2",a);
1923  me->setBinLabel(2,"ME -4/1",a);
1924  me->setBinLabel(3,"ME -3/2",a);
1925  me->setBinLabel(4,"ME -3/1",a);
1926  me->setBinLabel(5,"ME -2/2",a);
1927  me->setBinLabel(6,"ME -2/1",a);
1928  me->setBinLabel(7,"ME -1/3",a);
1929  me->setBinLabel(8,"ME -1/2",a);
1930  me->setBinLabel(9,"ME -1/1b",a);
1931  me->setBinLabel(10,"ME -1/1a",a);
1932  me->setBinLabel(11,"ME +1/1a",a);
1933  me->setBinLabel(12,"ME +1/1b",a);
1934  me->setBinLabel(13,"ME +1/2",a);
1935  me->setBinLabel(14,"ME +1/3",a);
1936  me->setBinLabel(15,"ME +2/1",a);
1937  me->setBinLabel(16,"ME +2/2",a);
1938  me->setBinLabel(17,"ME +3/1",a);
1939  me->setBinLabel(18,"ME +3/2",a);
1940  me->setBinLabel(19,"ME +4/1",a);
1941  me->setBinLabel(20,"ME +4/2",a);
1942  }
1943  else if (t == SMALL)
1944  {
1945  me->setBinLabel(1,"ME -4/1",a);
1946  me->setBinLabel(2,"ME -3/2",a);
1947  me->setBinLabel(3,"ME -3/1",a);
1948  me->setBinLabel(4,"ME -2/2",a);
1949  me->setBinLabel(5,"ME -2/1",a);
1950  me->setBinLabel(6,"ME -1/3",a);
1951  me->setBinLabel(7,"ME -1/2",a);
1952  me->setBinLabel(8,"ME -1/1b",a);
1953  me->setBinLabel(9,"ME -1/1a",a);
1954  me->setBinLabel(10,"ME +1/1a",a);
1955  me->setBinLabel(11,"ME +1/1b",a);
1956  me->setBinLabel(12,"ME +1/2",a);
1957  me->setBinLabel(13,"ME +1/3",a);
1958  me->setBinLabel(14,"ME +2/1",a);
1959  me->setBinLabel(15,"ME +2/2",a);
1960  me->setBinLabel(16,"ME +3/1",a);
1961  me->setBinLabel(17,"ME +3/2",a);
1962  me->setBinLabel(18,"ME +4/1",a);
1963  }
1964  }
1965 }
#define NULL
Definition: scimark2.h:8
double a
Definition: hdecay.h:121
void CSCOfflineMonitor::beginRun ( edm::Run const &  ,
edm::EventSetup const &   
)
virtual
void CSCOfflineMonitor::bookTheHists ( void  )

Definition at line 38 of file CSCOfflineMonitor.cc.

References applyCSClabels(), DQMStore::book1D(), DQMStore::book2D(), dbe, EXTENDED, finalizedHistograms_, hALCTgetBX, hALCTgetBX2Denominator, hALCTgetBX2DMeans, hALCTgetBX2DNumerator, hALCTgetBXChamberMeans, hALCTgetBXSerial, hALCTMatch, hALCTMatch2Denominator, hALCTMatch2DMeans, hALCTMatch2DNumerator, hALCTMatchChamberMeans, hALCTMatchSerial, hCLCTL1A, hCLCTL1A2Denominator, hCLCTL1A2DMeans, hCLCTL1A2DNumerator, hCLCTL1AChamberMeans, hCLCTL1ASerial, hCSCOccupancy, hEffDenominator, hORecHits, hORecHitsSerial, hOSegments, hOSegmentsSerial, hOStrips, hOStripsAndWiresAndCLCT, hOStripSerial, hOWires, hOWiresAndCLCT, hOWireSerial, hRHEff, hRHEff2, hRHGlobal, hRHnrechits, hRHRatioQ, hRHSTE, hRHSTE2, hRHsterr, hRHstpos, hRHSumQ, hRHTiming, hRHTimingAnode, hSChiSq, hSChiSqAll, hSChiSqProb, hSChiSqProbAll, hSEff, hSEff2, hSensitiveAreaEvt, hSGlobalPhi, hSGlobalTheta, hSnhits, hSnhitsAll, hSnSegments, hSResid, hSSTE, hSSTE2, hSTimeCathode, hSTimeCombined, hSTimeVsTOF, hSTimeVsZ, hStripEff2, hStripNFired, hStripNumber, hStripPed, hStripReadoutEff2, hStripSTE2, hWireEff2, hWirenGroupsTotal, hWireNumber, hWireSTE2, hWireTBin, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::setCurrentFolder(), SMALL, X, and Y.

Referenced by beginRun().

38  {
39 
40  finalizedHistograms_ = false;
41 
42  // Occupancies
43  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/Occupancy");
44  hCSCOccupancy = dbe->book1D("hCSCOccupancy","overall CSC occupancy",13,-0.5,12.5);
45  hCSCOccupancy->setBinLabel(2,"Total Events");
46  hCSCOccupancy->setBinLabel(4,"# Events with Wires");
47  hCSCOccupancy->setBinLabel(6,"# Events with Strips");
48  hCSCOccupancy->setBinLabel(8,"# Events with Wires&Strips");
49  hCSCOccupancy->setBinLabel(10,"# Events with Rechits");
50  hCSCOccupancy->setBinLabel(12,"# Events with Segments");
51  hOWiresAndCLCT = dbe->book2D("hOWiresAndCLCT","Wire and CLCT Digi Occupancy ",36,0.5,36.5,20,0.5,20.5);
52  hOWires = dbe->book2D("hOWires","Wire Digi Occupancy",36,0.5,36.5,20,0.5,20.5);
53  hOWireSerial = dbe->book1D("hOWireSerial","Wire Occupancy by Chamber Serial",601,-0.5,600.5);
54  hOWireSerial->setAxisTitle("Chamber Serial Number");
55  hOStrips = dbe->book2D("hOStrips","Strip Digi Occupancy",36,0.5,36.5,20,0.5,20.5);
56  hOStripSerial = dbe->book1D("hOStripSerial","Strip Occupancy by Chamber Serial",601,-0.5,600.5);
57  hOStripSerial->setAxisTitle("Chamber Serial Number");
58  hOStripsAndWiresAndCLCT = dbe->book2D("hOStripsAndWiresAndCLCT","Strip And Wire And CLCT Digi Occupancy",36,0.5,36.5,20,0.5,20.5);
60  hORecHits = dbe->book2D("hORecHits","RecHit Occupancy",36,0.5,36.5,20,0.5,20.5);
61  hORecHitsSerial = dbe->book1D("hORecHitSerial","RecHit Occupancy by Chamber Serial",601,-0.5,600.5);
62  hORecHitsSerial->setAxisTitle("Chamber Serial Number");
63  hOSegments = dbe->book2D("hOSegments","Segment Occupancy",36,0.5,36.5,20,0.5,20.5);
64  hOSegmentsSerial = dbe->book1D("hOSegmentSerial","Segment Occupancy by Chamber Serial",601,-0.5,600.5);
65  hOSegmentsSerial->setAxisTitle("Chamber Serial Number");
66 
67  // wire digis
68  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/Digis");
69  hWirenGroupsTotal = dbe->book1D("hWirenGroupsTotal","Fired Wires per Event; # Wiregroups Fired",61,-0.5,60.5);
70  hWireTBin.push_back(dbe->book1D("hWireTBin_m42","Wire TBin Fired (ME -4/2); Time Bin (25ns)",17,-0.5,16.5));
71  hWireTBin.push_back(dbe->book1D("hWireTBin_m41","Wire TBin Fired (ME -4/1); Time Bin (25ns)",17,-0.5,16.5));
72  hWireTBin.push_back(dbe->book1D("hWireTBin_m32","Wire TBin Fired (ME -3/2); Time Bin (25ns)",17,-0.5,16.5));
73  hWireTBin.push_back(dbe->book1D("hWireTBin_m31","Wire TBin Fired (ME -3/1); Time Bin (25ns)",17,-0.5,16.5));
74  hWireTBin.push_back(dbe->book1D("hWireTBin_m22","Wire TBin Fired (ME -2/2); Time Bin (25ns)",17,-0.5,16.5));
75  hWireTBin.push_back(dbe->book1D("hWireTBin_m21","Wire TBin Fired (ME -2/1); Time Bin (25ns)",17,-0.5,16.5));
76  hWireTBin.push_back(dbe->book1D("hWireTBin_m11a","Wire TBin Fired (ME -1/1a); Time Bin (25ns)",17,-0.5,16.5));
77  hWireTBin.push_back(dbe->book1D("hWireTBin_m13","Wire TBin Fired (ME -1/3); Time Bin (25ns)",17,-0.5,16.5));
78  hWireTBin.push_back(dbe->book1D("hWireTBin_m12","Wire TBin Fired (ME -1/2); Time Bin (25ns)",17,-0.5,16.5));
79  hWireTBin.push_back(dbe->book1D("hWireTBin_m11b","Wire TBin Fired (ME -1/1b); Time Bin (25ns)",17,-0.5,16.5));
80  hWireTBin.push_back(dbe->book1D("hWireTBin_p11b","Wire TBin Fired (ME +1/1b); Time Bin (25ns)",17,-0.5,16.5));
81  hWireTBin.push_back(dbe->book1D("hWireTBin_p12","Wire TBin Fired (ME +1/2); Time Bin (25ns)",17,-0.5,16.5));
82  hWireTBin.push_back(dbe->book1D("hWireTBin_p13","Wire TBin Fired (ME +1/3); Time Bin (25ns)",17,-0.5,16.5));
83  hWireTBin.push_back(dbe->book1D("hWireTBin_p11a","Wire TBin Fired (ME +1/1a); Time Bin (25ns)",17,-0.5,16.5));
84  hWireTBin.push_back(dbe->book1D("hWireTBin_p21","Wire TBin Fired (ME +2/1); Time Bin (25ns)",17,-0.5,16.5));
85  hWireTBin.push_back(dbe->book1D("hWireTBin_p22","Wire TBin Fired (ME +2/2); Time Bin (25ns)",17,-0.5,16.5));
86  hWireTBin.push_back(dbe->book1D("hWireTBin_p31","Wire TBin Fired (ME +3/1); Time Bin (25ns)",17,-0.5,16.5));
87  hWireTBin.push_back(dbe->book1D("hWireTBin_p32","Wire TBin Fired (ME +3/2); Time Bin (25ns)",17,-0.5,16.5));
88  hWireTBin.push_back(dbe->book1D("hWireTBin_p41","Wire TBin Fired (ME +4/1); Time Bin (25ns)",17,-0.5,16.5));
89  hWireTBin.push_back(dbe->book1D("hWireTBin_p42","Wire TBin Fired (ME +4/2); Time Bin (25ns)",17,-0.5,16.5));
90  hWireNumber.push_back(dbe->book1D("hWireNumber_m42","Wiregroup Number Fired (ME -4/2); Wiregroup #",113,-0.5,112.5));
91  hWireNumber.push_back(dbe->book1D("hWireNumber_m41","Wiregroup Number Fired (ME -4/1); Wiregroup #",113,-0.5,112.5));
92  hWireNumber.push_back(dbe->book1D("hWireNumber_m32","Wiregroup Number Fired (ME -3/2); Wiregroup #",113,-0.5,112.5));
93  hWireNumber.push_back(dbe->book1D("hWireNumber_m31","Wiregroup Number Fired (ME -3/1); Wiregroup #",113,-0.5,112.5));
94  hWireNumber.push_back(dbe->book1D("hWireNumber_m22","Wiregroup Number Fired (ME -2/2); Wiregroup #",113,-0.5,112.5));
95  hWireNumber.push_back(dbe->book1D("hWireNumber_m21","Wiregroup Number Fired (ME -2/1); Wiregroup #",113,-0.5,112.5));
96  hWireNumber.push_back(dbe->book1D("hWireNumber_m11a","Wiregroup Number Fired (ME -1/1a); Wiregroup #",113,-0.5,112.5));
97  hWireNumber.push_back(dbe->book1D("hWireNumber_m13","Wiregroup Number Fired (ME -1/3); Wiregroup #",113,-0.5,112.5));
98  hWireNumber.push_back(dbe->book1D("hWireNumber_m12","Wiregroup Number Fired (ME -1/2); Wiregroup #",113,-0.5,112.5));
99  hWireNumber.push_back(dbe->book1D("hWireNumber_m11b","Wiregroup Number Fired (ME -1/1b); Wiregroup #",113,-0.5,112.5));
100  hWireNumber.push_back(dbe->book1D("hWireNumber_p11b","Wiregroup Number Fired (ME +1/1b); Wiregroup #",113,-0.5,112.5));
101  hWireNumber.push_back(dbe->book1D("hWireNumber_p12","Wiregroup Number Fired (ME +1/2); Wiregroup #",113,-0.5,112.5));
102  hWireNumber.push_back(dbe->book1D("hWireNumber_p13","Wiregroup Number Fired (ME +1/3); Wiregroup #",113,-0.5,112.5));
103  hWireNumber.push_back(dbe->book1D("hWireNumber_p11a","Wiregroup Number Fired (ME +1/1a); Wiregroup #",113,-0.5,112.5));
104  hWireNumber.push_back(dbe->book1D("hWireNumber_p21","Wiregroup Number Fired (ME +2/1); Wiregroup #",113,-0.5,112.5));
105  hWireNumber.push_back(dbe->book1D("hWireNumber_p22","Wiregroup Number Fired (ME +2/2); Wiregroup #",113,-0.5,112.5));
106  hWireNumber.push_back(dbe->book1D("hWireNumber_p31","Wiregroup Number Fired (ME +3/1); Wiregroup #",113,-0.5,112.5));
107  hWireNumber.push_back(dbe->book1D("hWireNumber_p32","Wiregroup Number Fired (ME +3/2); Wiregroup #",113,-0.5,112.5));
108  hWireNumber.push_back(dbe->book1D("hWireNumber_p41","Wiregroup Number Fired (ME +4/1); Wiregroup #",113,-0.5,112.5));
109  hWireNumber.push_back(dbe->book1D("hWireNumber_p42","Wiregroup Number Fired (ME +4/2); Wiregroup #",113,-0.5,112.5));
110 
111  // strip digis
112  hStripNFired = dbe->book1D("hStripNFired","Fired Strips per Event; # Strips Fired (above 13 ADC)",101,-0.5,100.5);
113  hStripNumber.push_back(dbe->book1D("hStripNumber_m42","Strip Number Fired (ME -4/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
114  hStripNumber.push_back(dbe->book1D("hStripNumber_m41","Strip Number Fired (ME -4/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
115  hStripNumber.push_back(dbe->book1D("hStripNumber_m32","Strip Number Fired (ME -3/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
116  hStripNumber.push_back(dbe->book1D("hStripNumber_m31","Strip Number Fired (ME -3/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
117  hStripNumber.push_back(dbe->book1D("hStripNumber_m22","Strip Number Fired (ME -2/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
118  hStripNumber.push_back(dbe->book1D("hStripNumber_m21","Strip Number Fired (ME -2/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
119  hStripNumber.push_back(dbe->book1D("hStripNumber_m11a","Strip Number Fired (ME -1/1a); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
120  hStripNumber.push_back(dbe->book1D("hStripNumber_m13","Strip Number Fired (ME -1/3); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
121  hStripNumber.push_back(dbe->book1D("hStripNumber_m12","Strip Number Fired (ME -1/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
122  hStripNumber.push_back(dbe->book1D("hStripNumber_m11b","Strip Number Fired (ME -1/1b); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
123  hStripNumber.push_back(dbe->book1D("hStripNumber_p11b","Strip Number Fired (ME +1/1b); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
124  hStripNumber.push_back(dbe->book1D("hStripNumber_p12","Strip Number Fired (ME +1/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
125  hStripNumber.push_back(dbe->book1D("hStripNumber_p13","Strip Number Fired (ME +1/3); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
126  hStripNumber.push_back(dbe->book1D("hStripNumber_p11a","Strip Number Fired (ME +1/1a); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
127  hStripNumber.push_back(dbe->book1D("hStripNumber_p21","Strip Number Fired (ME +2/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
128  hStripNumber.push_back(dbe->book1D("hStripNumber_p22","Strip Number Fired (ME +2/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
129  hStripNumber.push_back(dbe->book1D("hStripNumber_p31","Strip Number Fired (ME +3/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
130  hStripNumber.push_back(dbe->book1D("hStripNumber_p32","Strip Number Fired (ME +3/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
131  hStripNumber.push_back(dbe->book1D("hStripNumber_p41","Strip Number Fired (ME +4/1); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
132  hStripNumber.push_back(dbe->book1D("hStripNumber_p42","Stripgroup Number Fired (ME +4/2); Strip # Fired (above 13 ADC)",81,-0.5,80.5));
133 
134  //Pedestal Noise Plots
135  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/PedestalNoise");
136  hStripPed.push_back(dbe->book1D("hStripPedMEm42","Pedestal Noise Distribution Chamber ME -4/2; ADC Counts",50,-25.,25.));
137  hStripPed.push_back(dbe->book1D("hStripPedMEm41","Pedestal Noise Distribution Chamber ME -4/1; ADC Counts",50,-25.,25.));
138  hStripPed.push_back(dbe->book1D("hStripPedMEm32","Pedestal Noise Distribution Chamber ME -3/2; ADC Counts",50,-25.,25.));
139  hStripPed.push_back(dbe->book1D("hStripPedMEm31","Pedestal Noise Distribution Chamber ME -3/1; ADC Counts",50,-25.,25.));
140  hStripPed.push_back(dbe->book1D("hStripPedMEm22","Pedestal Noise Distribution Chamber ME -2/2; ADC Counts",50,-25.,25.));
141  hStripPed.push_back(dbe->book1D("hStripPedMEm21","Pedestal Noise Distribution Chamber ME -2/1; ADC Counts",50,-25.,25.));
142  hStripPed.push_back(dbe->book1D("hStripPedMEm11a","Pedestal Noise Distribution Chamber ME -1/1; ADC Counts",50,-25.,25.));
143  hStripPed.push_back(dbe->book1D("hStripPedMEm13","Pedestal Noise Distribution Chamber ME -1/3; ADC Counts",50,-25.,25.));
144  hStripPed.push_back(dbe->book1D("hStripPedMEm12","Pedestal Noise Distribution Chamber ME -1/2; ADC Counts",50,-25.,25.));
145  hStripPed.push_back(dbe->book1D("hStripPedMEm11b","Pedestal Noise Distribution Chamber ME -1/1; ADC Counts",50,-25.,25.));
146  hStripPed.push_back(dbe->book1D("hStripPedMEp11b","Pedestal Noise Distribution Chamber ME +1/1; ADC Counts",50,-25.,25.));
147  hStripPed.push_back(dbe->book1D("hStripPedMEp12","Pedestal Noise Distribution Chamber ME +1/2; ADC Counts",50,-25.,25.));
148  hStripPed.push_back(dbe->book1D("hStripPedMEp13","Pedestal Noise Distribution Chamber ME +1/3; ADC Counts",50,-25.,25.));
149  hStripPed.push_back(dbe->book1D("hStripPedMEp11a","Pedestal Noise Distribution Chamber ME +1/1; ADC Counts",50,-25.,25.));
150  hStripPed.push_back(dbe->book1D("hStripPedMEp21","Pedestal Noise Distribution Chamber ME +2/1; ADC Counts",50,-25.,25.));
151  hStripPed.push_back(dbe->book1D("hStripPedMEp22","Pedestal Noise Distribution Chamber ME +2/2; ADC Counts",50,-25.,25.));
152  hStripPed.push_back(dbe->book1D("hStripPedMEp31","Pedestal Noise Distribution Chamber ME +3/1; ADC Counts",50,-25.,25.));
153  hStripPed.push_back(dbe->book1D("hStripPedMEp32","Pedestal Noise Distribution Chamber ME +3/2; ADC Counts",50,-25.,25.));
154  hStripPed.push_back(dbe->book1D("hStripPedMEp41","Pedestal Noise Distribution Chamber ME +4/1; ADC Counts",50,-25.,25.));
155  hStripPed.push_back(dbe->book1D("hStripPedMEp42","Pedestal Noise Distribution Chamber ME +4/2; ADC Counts",50,-25.,25.));
156 
157  // recHits
158  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/recHits");
159  hRHnrechits = dbe->book1D("hRHnrechits","recHits per Event (all chambers); # of RecHits",50,0,50);
160  hRHGlobal.push_back(dbe->book2D("hRHGlobalp1","recHit global X,Y station +1; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
161  hRHGlobal.push_back(dbe->book2D("hRHGlobalp2","recHit global X,Y station +2; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
162  hRHGlobal.push_back(dbe->book2D("hRHGlobalp3","recHit global X,Y station +3; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
163  hRHGlobal.push_back(dbe->book2D("hRHGlobalp4","recHit global X,Y station +4; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
164  hRHGlobal.push_back(dbe->book2D("hRHGlobalm1","recHit global X,Y station -1; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
165  hRHGlobal.push_back(dbe->book2D("hRHGlobalm2","recHit global X,Y station -2; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
166  hRHGlobal.push_back(dbe->book2D("hRHGlobalm3","recHit global X,Y station -3; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
167  hRHGlobal.push_back(dbe->book2D("hRHGlobalm4","recHit global X,Y station -4; Global X (cm); Global Y (cm)",100,-800.,800.,100,-800.,800.));
168  hRHSumQ.push_back(dbe->book1D("hRHSumQm42","Sum 3x3 recHit Charge (ME -4/2); ADC counts",100,0,2000));
169  hRHSumQ.push_back(dbe->book1D("hRHSumQm41","Sum 3x3 recHit Charge (ME -4/1); ADC counts",100,0,2000));
170  hRHSumQ.push_back(dbe->book1D("hRHSumQm32","Sum 3x3 recHit Charge (ME -3/2); ADC counts",100,0,2000));
171  hRHSumQ.push_back(dbe->book1D("hRHSumQm31","Sum 3x3 recHit Charge (ME -3/1); ADC counts",100,0,2000));
172  hRHSumQ.push_back(dbe->book1D("hRHSumQm22","Sum 3x3 recHit Charge (ME -2/2); ADC counts",100,0,2000));
173  hRHSumQ.push_back(dbe->book1D("hRHSumQm21","Sum 3x3 recHit Charge (ME -2/1); ADC counts",100,0,2000));
174  hRHSumQ.push_back(dbe->book1D("hRHSumQm11a","Sum 3x3 recHit Charge (ME -1/1a); ADC counts",100,0,4000));
175  hRHSumQ.push_back(dbe->book1D("hRHSumQm13","Sum 3x3 recHit Charge (ME -1/3); ADC counts",100,0,2000));
176  hRHSumQ.push_back(dbe->book1D("hRHSumQm12","Sum 3x3 recHit Charge (ME -1/2); ADC counts",100,0,2000));
177  hRHSumQ.push_back(dbe->book1D("hRHSumQm11b","Sum 3x3 recHit Charge (ME -1/1b); ADC counts",100,0,4000));
178  hRHSumQ.push_back(dbe->book1D("hRHSumQp11b","Sum 3x3 recHit Charge (ME +1/1b); ADC counts",100,0,4000));
179  hRHSumQ.push_back(dbe->book1D("hRHSumQp12","Sum 3x3 recHit Charge (ME +1/2); ADC counts",100,0,2000));
180  hRHSumQ.push_back(dbe->book1D("hRHSumQp13","Sum 3x3 recHit Charge (ME +1/3); ADC counts",100,0,2000));
181  hRHSumQ.push_back(dbe->book1D("hRHSumQp11a","Sum 3x3 recHit Charge (ME +1/1a); ADC counts",100,0,4000));
182  hRHSumQ.push_back(dbe->book1D("hRHSumQp21","Sum 3x3 recHit Charge (ME +2/1); ADC counts",100,0,2000));
183  hRHSumQ.push_back(dbe->book1D("hRHSumQp22","Sum 3x3 recHit Charge (ME +2/2); ADC counts",100,0,2000));
184  hRHSumQ.push_back(dbe->book1D("hRHSumQp31","Sum 3x3 recHit Charge (ME +3/1); ADC counts",100,0,2000));
185  hRHSumQ.push_back(dbe->book1D("hRHSumQp32","Sum 3x3 recHit Charge (ME +3/2); ADC counts",100,0,2000));
186  hRHSumQ.push_back(dbe->book1D("hRHSumQp41","Sum 3x3 recHit Charge (ME +4/1); ADC counts",100,0,2000));
187  hRHSumQ.push_back(dbe->book1D("hRHSumQp42","Sum 3x3 recHit Charge (ME +4/2); ADC counts",100,0,2000));
188  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm42","Charge Ratio (Ql+Qr)/Qt (ME -4/2); (Ql+Qr)/Qt",100,-0.1,1.1));
189  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm41","Charge Ratio (Ql+Qr)/Qt (ME -4/1); (Ql+Qr)/Qt",100,-0.1,1.1));
190  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm32","Charge Ratio (Ql+Qr)/Qt (ME -3/2); (Ql+Qr)/Qt",100,-0.1,1.1));
191  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm31","Charge Ratio (Ql+Qr)/Qt (ME -3/1); (Ql+Qr)/Qt",100,-0.1,1.1));
192  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm22","Charge Ratio (Ql+Qr)/Qt (ME -2/2); (Ql+Qr)/Qt",100,-0.1,1.1));
193  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm21","Charge Ratio (Ql+Qr)/Qt (ME -2/1); (Ql+Qr)/Qt",100,-0.1,1.1));
194  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm11a","Charge Ratio (Ql+Qr)/Qt (ME -1/1a); (Ql+Qr)/Qt",100,-0.1,1.1));
195  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm13","Charge Ratio (Ql+Qr)/Qt (ME -1/3); (Ql+Qr)/Qt",100,-0.1,1.1));
196  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm12","Charge Ratio (Ql+Qr)/Qt (ME -1/2); (Ql+Qr)/Qt",100,-0.1,1.1));
197  hRHRatioQ.push_back(dbe->book1D("hRHRatioQm11b","Charge Ratio (Ql+Qr)/Qt (ME -1/1b); (Ql+Qr)/Qt",100,-0.1,1.1));
198  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp11b","Charge Ratio (Ql+Qr)/Qt (ME +1/1b); (Ql+Qr)/Qt",100,-0.1,1.1));
199  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp12","Charge Ratio (Ql+Qr)/Qt (ME +1/2); (Ql+Qr)/Qt",100,-0.1,1.1));
200  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp13","Charge Ratio (Ql+Qr)/Qt (ME +1/3); (Ql+Qr)/Qt",100,-0.1,1.1));
201  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp11a","Charge Ratio (Ql+Qr)/Qt (ME +1/1a); (Ql+Qr)/Qt",100,-0.1,1.1));
202  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp21","Charge Ratio (Ql+Qr)/Qt (ME +2/1); (Ql+Qr)/Qt",100,-0.1,1.1));
203  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp22","Charge Ratio (Ql+Qr)/Qt (ME +2/2); (Ql+Qr)/Qt",100,-0.1,1.1));
204  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp31","Charge Ratio (Ql+Qr)/Qt (ME +3/1); (Ql+Qr)/Qt",100,-0.1,1.1));
205  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp32","Charge Ratio (Ql+Qr)/Qt (ME +3/2); (Ql+Qr)/Qt",100,-0.1,1.1));
206  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp41","Charge Ratio (Ql+Qr)/Qt (ME +4/1); (Ql+Qr)/Qt",100,-0.1,1.1));
207  hRHRatioQ.push_back(dbe->book1D("hRHRatioQp42","Charge Ratio (Ql+Qr)/Qt (ME +4/2); (Ql+Qr)/Qt",100,-0.1,1.1));
208  hRHTiming.push_back(dbe->book1D("hRHTimingm42","recHit Time (ME -4/2); ns",200,-500.,500.));
209  hRHTiming.push_back(dbe->book1D("hRHTimingm41","recHit Time (ME -4/1); ns",200,-500.,500.));
210  hRHTiming.push_back(dbe->book1D("hRHTimingm32","recHit Time (ME -3/2); ns",200,-500.,500.));
211  hRHTiming.push_back(dbe->book1D("hRHTimingm31","recHit Time (ME -3/1); ns",200,-500.,500.));
212  hRHTiming.push_back(dbe->book1D("hRHTimingm22","recHit Time (ME -2/2); ns",200,-500.,500.));
213  hRHTiming.push_back(dbe->book1D("hRHTimingm21","recHit Time (ME -2/1); ns",200,-500.,500.));
214  hRHTiming.push_back(dbe->book1D("hRHTimingm11a","recHit Time (ME -1/1a); ns",200,-500.,500.));
215  hRHTiming.push_back(dbe->book1D("hRHTimingm13","recHit Time (ME -1/3); ns",200,-500.,500.));
216  hRHTiming.push_back(dbe->book1D("hRHTimingm12","recHit Time (ME -1/2); ns",200,-500.,500.));
217  hRHTiming.push_back(dbe->book1D("hRHTimingm11b","recHit Time (ME -1/1b); ns",200,-500.,500.));
218  hRHTiming.push_back(dbe->book1D("hRHTimingp11b","recHit Time (ME +1/1b); ns",200,-500.,500.));
219  hRHTiming.push_back(dbe->book1D("hRHTimingp12","recHit Time (ME +1/2); ns",200,-500.,500.));
220  hRHTiming.push_back(dbe->book1D("hRHTimingp13","recHit Time (ME +1/3); ns",200,-500.,500.));
221  hRHTiming.push_back(dbe->book1D("hRHTimingp11a","recHit Time (ME +1/1a); ns",200,-500.,500.));
222  hRHTiming.push_back(dbe->book1D("hRHTimingp21","recHit Time (ME +2/1); ns",200,-500.,500.));
223  hRHTiming.push_back(dbe->book1D("hRHTimingp22","recHit Time (ME +2/2); ns",200,-500.,500.));
224  hRHTiming.push_back(dbe->book1D("hRHTimingp31","recHit Time (ME +3/1); ns",200,-500.,500.));
225  hRHTiming.push_back(dbe->book1D("hRHTimingp32","recHit Time (ME +3/2); ns",200,-500.,500.));
226  hRHTiming.push_back(dbe->book1D("hRHTimingp41","recHit Time (ME +4/1); ns",200,-500.,500.));
227  hRHTiming.push_back(dbe->book1D("hRHTimingp42","recHit Time (ME +4/2); ns",200,-500.,500.));
228  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem42","Anode recHit Time (ME -4/2); ns",80,-500.,500.));
229  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem41","Anode recHit Time (ME -4/1); ns",80,-500.,500.));
230  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem32","Anode recHit Time (ME -3/2); ns",80,-500.,500.));
231  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem31","Anode recHit Time (ME -3/1); ns",80,-500.,500.));
232  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem22","Anode recHit Time (ME -2/2); ns",80,-500.,500.));
233  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem21","Anode recHit Time (ME -2/1); ns",80,-500.,500.));
234  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem11a","Anode recHit Time (ME -1/1a); ns",80,-500.,500.));
235  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem13","Anode recHit Time (ME -1/3); ns",80,-500.,500.));
236  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem12","Anode recHit Time (ME -1/2); ns",80,-500.,500.));
237  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodem11b","Anode recHit Time (ME -1/1b); ns",80,-500.,500.));
238  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep11b","Anode recHit Time (ME +1/1b); ns",80,-500.,500.));
239  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep12","Anode recHit Time (ME +1/2); ns",80,-500.,500.));
240  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep13","Anode recHit Time (ME +1/3); ns",80,-500.,500.));
241  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep11a","Anode recHit Time (ME +1/1a); ns",80,-500.,500.));
242  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep21","Anode recHit Time (ME +2/1); ns",80,-500.,500.));
243  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep22","Anode recHit Time (ME +2/2); ns",80,-500.,500.));
244  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep31","Anode recHit Time (ME +3/1); ns",80,-500.,500.));
245  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep32","Anode recHit Time (ME +3/2); ns",80,-500.,500.));
246  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep41","Anode recHit Time (ME +4/1); ns",80,-500.,500.));
247  hRHTimingAnode.push_back(dbe->book1D("hRHTimingAnodep42","Anode recHit Time (ME +4/2); ns",80,-500.,500.));
248  hRHstpos.push_back(dbe->book1D("hRHstposm42","Reconstructed Position on Strip (ME -4/2); Strip Widths",120,-0.6,0.6));
249  hRHstpos.push_back(dbe->book1D("hRHstposm41","Reconstructed Position on Strip (ME -4/1); Strip Widths",120,-0.6,0.6));
250  hRHstpos.push_back(dbe->book1D("hRHstposm32","Reconstructed Position on Strip (ME -3/2); Strip Widths",120,-0.6,0.6));
251  hRHstpos.push_back(dbe->book1D("hRHstposm31","Reconstructed Position on Strip (ME -3/1); Strip Widths",120,-0.6,0.6));
252  hRHstpos.push_back(dbe->book1D("hRHstposm22","Reconstructed Position on Strip (ME -2/2); Strip Widths",120,-0.6,0.6));
253  hRHstpos.push_back(dbe->book1D("hRHstposm21","Reconstructed Position on Strip (ME -2/1); Strip Widths",120,-0.6,0.6));
254  hRHstpos.push_back(dbe->book1D("hRHstposm11a","Reconstructed Position on Strip (ME -1/1a); Strip Widths",120,-0.6,0.6));
255  hRHstpos.push_back(dbe->book1D("hRHstposm13","Reconstructed Position on Strip (ME -1/3); Strip Widths",120,-0.6,0.6));
256  hRHstpos.push_back(dbe->book1D("hRHstposm12","Reconstructed Position on Strip (ME -1/2); Strip Widths",120,-0.6,0.6));
257  hRHstpos.push_back(dbe->book1D("hRHstposm11b","Reconstructed Position on Strip (ME -1/1b); Strip Widths",120,-0.6,0.6));
258  hRHstpos.push_back(dbe->book1D("hRHstposp11b","Reconstructed Position on Strip (ME +1/1b); Strip Widths",120,-0.6,0.6));
259  hRHstpos.push_back(dbe->book1D("hRHstposp12","Reconstructed Position on Strip (ME +1/2); Strip Widths",120,-0.6,0.6));
260  hRHstpos.push_back(dbe->book1D("hRHstposp13","Reconstructed Position on Strip (ME +1/3); Strip Widths",120,-0.6,0.6));
261  hRHstpos.push_back(dbe->book1D("hRHstposp11a","Reconstructed Position on Strip (ME +1/1a); Strip Widths",120,-0.6,0.6));
262  hRHstpos.push_back(dbe->book1D("hRHstposp21","Reconstructed Position on Strip (ME +2/1); Strip Widths",120,-0.6,0.6));
263  hRHstpos.push_back(dbe->book1D("hRHstposp22","Reconstructed Position on Strip (ME +2/2); Strip Widths",120,-0.6,0.6));
264  hRHstpos.push_back(dbe->book1D("hRHstposp31","Reconstructed Position on Strip (ME +3/1); Strip Widths",120,-0.6,0.6));
265  hRHstpos.push_back(dbe->book1D("hRHstposp32","Reconstructed Position on Strip (ME +3/2); Strip Widths",120,-0.6,0.6));
266  hRHstpos.push_back(dbe->book1D("hRHstposp41","Reconstructed Position on Strip (ME +4/1); Strip Widths",120,-0.6,0.6));
267  hRHstpos.push_back(dbe->book1D("hRHstposp42","Reconstructed Position on Strip (ME +4/2); Strip Widths",120,-0.6,0.6));
268  hRHsterr.push_back(dbe->book1D("hRHsterrm42","Estimated Error on Strip Measurement (ME -4/2); Strip Widths",75,-0.01,0.24));
269  hRHsterr.push_back(dbe->book1D("hRHsterrm41","Estimated Error on Strip Measurement (ME -4/1); Strip Widths",75,-0.01,0.24));
270  hRHsterr.push_back(dbe->book1D("hRHsterrm32","Estimated Error on Strip Measurement (ME -3/2); Strip Widths",75,-0.01,0.24));
271  hRHsterr.push_back(dbe->book1D("hRHsterrm31","Estimated Error on Strip Measurement (ME -3/1); Strip Widths",75,-0.01,0.24));
272  hRHsterr.push_back(dbe->book1D("hRHsterrm22","Estimated Error on Strip Measurement (ME -2/2); Strip Widths",75,-0.01,0.24));
273  hRHsterr.push_back(dbe->book1D("hRHsterrm21","Estimated Error on Strip Measurement (ME -2/1); Strip Widths",75,-0.01,0.24));
274  hRHsterr.push_back(dbe->book1D("hRHsterrm11a","Estimated Error on Strip Measurement (ME -1/1a); Strip Widths",75,-0.01,0.24));
275  hRHsterr.push_back(dbe->book1D("hRHsterrm13","Estimated Error on Strip Measurement (ME -1/3); Strip Widths",75,-0.01,0.24));
276  hRHsterr.push_back(dbe->book1D("hRHsterrm12","Estimated Error on Strip Measurement (ME -1/2); Strip Widths",75,-0.01,0.24));
277  hRHsterr.push_back(dbe->book1D("hRHsterrm11b","Estimated Error on Strip Measurement (ME -1/1b); Strip Widths",75,-0.01,0.24));
278  hRHsterr.push_back(dbe->book1D("hRHsterrp11b","Estimated Error on Strip Measurement (ME +1/1b); Strip Widths",75,-0.01,0.24));
279  hRHsterr.push_back(dbe->book1D("hRHsterrp12","Estimated Error on Strip Measurement (ME +1/2); Strip Widths",75,-0.01,0.24));
280  hRHsterr.push_back(dbe->book1D("hRHsterrp13","Estimated Error on Strip Measurement (ME +1/3); Strip Widths",75,-0.01,0.24));
281  hRHsterr.push_back(dbe->book1D("hRHsterrp11a","Estimated Error on Strip Measurement (ME +1/1a); Strip Widths",75,-0.01,0.24));
282  hRHsterr.push_back(dbe->book1D("hRHsterrp21","Estimated Error on Strip Measurement (ME +2/1); Strip Widths",75,-0.01,0.24));
283  hRHsterr.push_back(dbe->book1D("hRHsterrp22","Estimated Error on Strip Measurement (ME +2/2); Strip Widths",75,-0.01,0.24));
284  hRHsterr.push_back(dbe->book1D("hRHsterrp31","Estimated Error on Strip Measurement (ME +3/1); Strip Widths",75,-0.01,0.24));
285  hRHsterr.push_back(dbe->book1D("hRHsterrp32","Estimated Error on Strip Measurement (ME +3/2); Strip Widths",75,-0.01,0.24));
286  hRHsterr.push_back(dbe->book1D("hRHsterrp41","Estimated Error on Strip Measurement (ME +4/1); Strip Widths",75,-0.01,0.24));
287  hRHsterr.push_back(dbe->book1D("hRHsterrp42","Estimated Error on Strip Measurement (ME +4/2); Strip Widths",75,-0.01,0.24));
288 
289 
290  // segments
291  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/Segments");
292  hSnSegments = dbe->book1D("hSnSegments","Number of Segments per Event; # of Segments",11,-0.5,10.5);
293  hSnhitsAll = dbe->book1D("hSnhits","N hits on Segments; # of hits",8,-0.5,7.5);
294  hSnhits.push_back(dbe->book1D("hSnhitsm42","# of hits on Segments (ME -4/2); # of hits",8,-0.5,7.5));
295  hSnhits.push_back(dbe->book1D("hSnhitsm41","# of hits on Segments (ME -4/1); # of hits",8,-0.5,7.5));
296  hSnhits.push_back(dbe->book1D("hSnhitsm32","# of hits on Segments (ME -3/2); # of hits",8,-0.5,7.5));
297  hSnhits.push_back(dbe->book1D("hSnhitsm31","# of hits on Segments (ME -3/1); # of hits",8,-0.5,7.5));
298  hSnhits.push_back(dbe->book1D("hSnhitsm22","# of hits on Segments (ME -2/2); # of hits",8,-0.5,7.5));
299  hSnhits.push_back(dbe->book1D("hSnhitsm21","# of hits on Segments (ME -2/1); # of hits",8,-0.5,7.5));
300  hSnhits.push_back(dbe->book1D("hSnhitsm11a","# of hits on Segments (ME -1/1a); # of hits",8,-0.5,7.5));
301  hSnhits.push_back(dbe->book1D("hSnhitsm13","# of hits on Segments (ME -1/3); # of hits",8,-0.5,7.5));
302  hSnhits.push_back(dbe->book1D("hSnhitsm12","# of hits on Segments (ME -1/2); # of hits",8,-0.5,7.5));
303  hSnhits.push_back(dbe->book1D("hSnhitsm11b","# of hits on Segments (ME -1/1b); # of hits",8,-0.5,7.5));
304  hSnhits.push_back(dbe->book1D("hSnhitsp11b","# of hits on Segments (ME +1/1b); # of hits",8,-0.5,7.5));
305  hSnhits.push_back(dbe->book1D("hSnhitsp12","# of hits on Segments (ME +1/2); # of hits",8,-0.5,7.5));
306  hSnhits.push_back(dbe->book1D("hSnhitsp13","# of hits on Segments (ME +1/3); # of hits",8,-0.5,7.5));
307  hSnhits.push_back(dbe->book1D("hSnhitsp11a","# of hits on Segments (ME +1/1a); # of hits",8,-0.5,7.5));
308  hSnhits.push_back(dbe->book1D("hSnhitsp21","# of hits on Segments (ME +2/1); # of hits",8,-0.5,7.5));
309  hSnhits.push_back(dbe->book1D("hSnhitsp22","# of hits on Segments (ME +2/2); # of hits",8,-0.5,7.5));
310  hSnhits.push_back(dbe->book1D("hSnhitsp31","# of hits on Segments (ME +3/1); # of hits",8,-0.5,7.5));
311  hSnhits.push_back(dbe->book1D("hSnhitsp32","# of hits on Segments (ME +3/2); # of hits",8,-0.5,7.5));
312  hSnhits.push_back(dbe->book1D("hSnhitsp41","# of hits on Segments (ME +4/1); # of hits",8,-0.5,7.5));
313  hSnhits.push_back(dbe->book1D("hSnhitsp42","# of hits on Segments (ME +4/2); # of hits",8,-0.5,7.5));
314  hSChiSqAll = dbe->book1D("hSChiSq","Segment Normalized Chi2; Chi2/ndof",110,-0.05,10.5);
315  hSChiSq.push_back(dbe->book1D("hSChiSqm42","Segment Normalized Chi2 (ME -4/2); Chi2/ndof",110,-0.05,10.5));
316  hSChiSq.push_back(dbe->book1D("hSChiSqm41","Segment Normalized Chi2 (ME -4/1); Chi2/ndof",110,-0.05,10.5));
317  hSChiSq.push_back(dbe->book1D("hSChiSqm32","Segment Normalized Chi2 (ME -3/2); Chi2/ndof",110,-0.05,10.5));
318  hSChiSq.push_back(dbe->book1D("hSChiSqm31","Segment Normalized Chi2 (ME -3/1); Chi2/ndof",110,-0.05,10.5));
319  hSChiSq.push_back(dbe->book1D("hSChiSqm22","Segment Normalized Chi2 (ME -2/2); Chi2/ndof",110,-0.05,10.5));
320  hSChiSq.push_back(dbe->book1D("hSChiSqm21","Segment Normalized Chi2 (ME -2/1); Chi2/ndof",110,-0.05,10.5));
321  hSChiSq.push_back(dbe->book1D("hSChiSqm11a","Segment Normalized Chi2 (ME -1/1a); Chi2/ndof",110,-0.05,10.5));
322  hSChiSq.push_back(dbe->book1D("hSChiSqm13","Segment Normalized Chi2 (ME -1/3); Chi2/ndof",110,-0.05,10.5));
323  hSChiSq.push_back(dbe->book1D("hSChiSqm12","Segment Normalized Chi2 (ME -1/2); Chi2/ndof",110,-0.05,10.5));
324  hSChiSq.push_back(dbe->book1D("hSChiSqm11b","Segment Normalized Chi2 (ME -1/1b); Chi2/ndof",110,-0.05,10.5));
325  hSChiSq.push_back(dbe->book1D("hSChiSqp11b","Segment Normalized Chi2 (ME +1/1b); Chi2/ndof",110,-0.05,10.5));
326  hSChiSq.push_back(dbe->book1D("hSChiSqp12","Segment Normalized Chi2 (ME +1/2); Chi2/ndof",110,-0.05,10.5));
327  hSChiSq.push_back(dbe->book1D("hSChiSqp13","Segment Normalized Chi2 (ME +1/3); Chi2/ndof",110,-0.05,10.5));
328  hSChiSq.push_back(dbe->book1D("hSChiSqp11a","Segment Normalized Chi2 (ME +1/1a); Chi2/ndof",110,-0.05,10.5));
329  hSChiSq.push_back(dbe->book1D("hSChiSqp21","Segment Normalized Chi2 (ME +2/1); Chi2/ndof",110,-0.05,10.5));
330  hSChiSq.push_back(dbe->book1D("hSChiSqp22","Segment Normalized Chi2 (ME +2/2); Chi2/ndof",110,-0.05,10.5));
331  hSChiSq.push_back(dbe->book1D("hSChiSqp31","Segment Normalized Chi2 (ME +3/1); Chi2/ndof",110,-0.05,10.5));
332  hSChiSq.push_back(dbe->book1D("hSChiSqp32","Segment Normalized Chi2 (ME +3/2); Chi2/ndof",110,-0.05,10.5));
333  hSChiSq.push_back(dbe->book1D("hSChiSqp41","Segment Normalized Chi2 (ME +4/1); Chi2/ndof",110,-0.05,10.5));
334  hSChiSq.push_back(dbe->book1D("hSChiSqp42","Segment Normalized Chi2 (ME +4/2); Chi2/ndof",110,-0.05,10.5));
335  hSChiSqProbAll = dbe->book1D("hSChiSqProb","Segment chi2 Probability; Probability",110,-0.05,1.05);
336  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm42","Segment chi2 Probability (ME -4/2); Probability",110,-0.05,1.05));
337  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm41","Segment chi2 Probability (ME -4/1); Probability",110,-0.05,1.05));
338  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm32","Segment chi2 Probability (ME -3/2); Probability",110,-0.05,1.05));
339  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm31","Segment chi2 Probability (ME -3/1); Probability",110,-0.05,1.05));
340  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm22","Segment chi2 Probability (ME -2/2); Probability",110,-0.05,1.05));
341  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm21","Segment chi2 Probability (ME -2/1); Probability",110,-0.05,1.05));
342  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm11a","Segment chi2 Probability (ME -1/1a); Probability",110,-0.05,1.05));
343  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm13","Segment chi2 Probability (ME -1/3); Probability",110,-0.05,1.05));
344  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm12","Segment chi2 Probability (ME -1/2); Probability",110,-0.05,1.05));
345  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbm11b","Segment chi2 Probability (ME -1/1b); Probability",110,-0.05,1.05));
346  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp11b","Segment chi2 Probability (ME +1/1b); Probability",110,-0.05,1.05));
347  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp12","Segment chi2 Probability (ME +1/2); Probability",110,-0.05,1.05));
348  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp13","Segment chi2 Probability (ME +1/3); Probability",110,-0.05,1.05));
349  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp11a","Segment chi2 Probability (ME +1/1a); Probability",110,-0.05,1.05));
350  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp21","Segment chi2 Probability (ME +2/1); Probability",110,-0.05,1.05));
351  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp22","Segment chi2 Probability (ME +2/2); Probability",110,-0.05,1.05));
352  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp31","Segment chi2 Probability (ME +3/1); Probability",110,-0.05,1.05));
353  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp32","Segment chi2 Probability (ME +3/2); Probability",110,-0.05,1.05));
354  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp41","Segment chi2 Probability (ME +4/1); Probability",110,-0.05,1.05));
355  hSChiSqProb.push_back(dbe->book1D("hSChiSqProbp42","Segment chi2 Probability (ME +4/2); Probability",110,-0.05,1.05));
356  hSGlobalTheta = dbe->book1D("hSGlobalTheta","Segment Direction (Global Theta); Global Theta (radians)",136,-0.1,3.3);
357  hSGlobalPhi = dbe->book1D("hSGlobalPhi","Segment Direction (Global Phi); Global Phi (radians)", 128,-3.2,3.2);
358  hSTimeCathode = dbe->book1D("hSTimeCathode", "Cathode Only Segment Time [ns]",200,-200,200);
359  hSTimeCombined = dbe->book1D("hSTimeCombined", "Segment Time (anode+cathode times) [ns]",200,-200,200);
360  hSTimeVsZ = dbe->book2D("hSTimeVsZ","Segment Time vs. Z; [ns] vs. [cm]",200,-1200,1200,200,-200,200);
361  hSTimeVsTOF = dbe->book2D("hSTimeVsTOF","Segment Time vs. Distance from IP; [ns] vs. [cm]",180,500,1400, 200,-200,200);
362  // Resolution
363  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/Resolution");
364  hSResid.push_back(dbe->book1D("hSResidm42","Fitted Position on Strip - Reconstructed for Layer 3 (ME -4/2); Strip Widths",100,-0.5,0.5));
365  hSResid.push_back(dbe->book1D("hSResidm41","Fitted Position on Strip - Reconstructed for Layer 3 (ME -4/1); Strip Widths",100,-0.5,0.5));
366  hSResid.push_back(dbe->book1D("hSResidm32","Fitted Position on Strip - Reconstructed for Layer 3 (ME -3/2); Strip Widths",100,-0.5,0.5));
367  hSResid.push_back(dbe->book1D("hSResidm31","Fitted Position on Strip - Reconstructed for Layer 3 (ME -3/1); Strip Widths",100,-0.5,0.5));
368  hSResid.push_back(dbe->book1D("hSResidm22","Fitted Position on Strip - Reconstructed for Layer 3 (ME -2/2); Strip Widths",100,-0.5,0.5));
369  hSResid.push_back(dbe->book1D("hSResidm21","Fitted Position on Strip - Reconstructed for Layer 3 (ME -2/1); Strip Widths",100,-0.5,0.5));
370  hSResid.push_back(dbe->book1D("hSResidm11a","Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/1a); Strip Widths",100,-0.5,0.5));
371  hSResid.push_back(dbe->book1D("hSResidm13","Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/3); Strip Widths",100,-0.5,0.5));
372  hSResid.push_back(dbe->book1D("hSResidm12","Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/2); Strip Widths",100,-0.5,0.5));
373  hSResid.push_back(dbe->book1D("hSResidm11b","Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/1b); Strip Widths",100,-0.5,0.5));
374  hSResid.push_back(dbe->book1D("hSResidp11b","Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/1b); Strip Widths",100,-0.5,0.5));
375  hSResid.push_back(dbe->book1D("hSResidp12","Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/2); Strip Widths",100,-0.5,0.5));
376  hSResid.push_back(dbe->book1D("hSResidp13","Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/3); Strip Widths",100,-0.5,0.5));
377  hSResid.push_back(dbe->book1D("hSResidp11a","Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/1a); Strip Widths",100,-0.5,0.5));
378  hSResid.push_back(dbe->book1D("hSResidp21","Fitted Position on Strip - Reconstructed for Layer 3 (ME +2/1); Strip Widths",100,-0.5,0.5));
379  hSResid.push_back(dbe->book1D("hSResidp22","Fitted Position on Strip - Reconstructed for Layer 3 (ME +2/2); Strip Widths",100,-0.5,0.5));
380  hSResid.push_back(dbe->book1D("hSResidp31","Fitted Position on Strip - Reconstructed for Layer 3 (ME +3/1); Strip Widths",100,-0.5,0.5));
381  hSResid.push_back(dbe->book1D("hSResidp32","Fitted Position on Strip - Reconstructed for Layer 3 (ME +3/2); Strip Widths",100,-0.5,0.5));
382  hSResid.push_back(dbe->book1D("hSResidp41","Fitted Position on Strip - Reconstructed for Layer 3 (ME +4/1); Strip Widths",100,-0.5,0.5));
383  hSResid.push_back(dbe->book1D("hSResidp42","Fitted Position on Strip - Reconstructed for Layer 3 (ME +4/2); Strip Widths",100,-0.5,0.5));
384 
385  // Efficiency
386 
387  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/Efficiency");
388  hSSTE = dbe->book1D("hSSTE","hSSTE",40,0.5,40.5);
389  hRHSTE = dbe->book1D("hRHSTE","hRHSTE",40,0.5,40.5);
390  hSEff = dbe->book1D("hSEff","Segment Efficiency",20,0.5,20.5);
391  hRHEff = dbe->book1D("hRHEff","recHit Efficiency",20,0.5,20.5);
392  hSSTE2 = dbe->book2D("hSSTE2","hSSTE2",36,0.5,36.5, 18, 0.5, 18.5);
393  hRHSTE2 = dbe->book2D("hRHSTE2","hRHSTE2",36,0.5,36.5, 18, 0.5, 18.5);
394  hStripSTE2 = dbe->book2D("hStripSTE2","hStripSTE2",36,0.5,36.5, 18, 0.5, 18.5);
395  hWireSTE2 = dbe->book2D("hWireSTE2","hWireSTE2",36,0.5,36.5, 18, 0.5, 18.5);
396  hEffDenominator = dbe->book2D("hEffDenominator","hEffDenominator",36,0.5,36.5, 18, 0.5, 18.5);
397  hSEff2 = dbe->book2D("hSEff2","Segment Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
398  hRHEff2 = dbe->book2D("hRHEff2","recHit Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
399  hStripReadoutEff2 = dbe->book2D("hStripReadoutEff2","strip readout ratio [(strip+clct+wires)/(clct+wires)] 2D",36,0.5,36.5, 20, 0.5, 20.5);
400  hStripReadoutEff2->setAxisTitle("Chamber #");
401  hStripEff2 = dbe->book2D("hStripEff2","strip Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
402  hWireEff2 = dbe->book2D("hWireEff2","wire Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
403  hSensitiveAreaEvt = dbe->book2D("hSensitiveAreaEvt","Events Passing Selection for Efficiency",36,0.5,36.5, 18, 0.5, 18.5);
404 
405  // BX Monitor for trigger synchronization
406  dbe->setCurrentFolder("CSC/CSCOfflineMonitor/BXMonitor");
407  hALCTgetBX = dbe->book1D("hALCTgetBX","ALCT position in ALCT-L1A match window [BX]",7,-0.5,6.5);
408  hALCTgetBXChamberMeans = dbe->book1D("hALCTgetBXChamberMeans","Chamber Mean ALCT position in ALCT-L1A match window [BX]",60,0,6);
409  hALCTgetBXSerial = dbe->book2D("hALCTgetBXSerial","ALCT position in ALCT-L1A match window [BX]",601,-0.5,600.5,7,-0.5,6.5);
410  hALCTgetBXSerial->setAxisTitle("Chamber Serial Number");
411  hALCTgetBX2DNumerator = dbe->book2D("hALCTgetBX2DNumerator","ALCT position in ALCT-L1A match window [BX] (sum)",36,0.5,36.5,20,0.5,20.5);
412  hALCTgetBX2DMeans = dbe->book2D("hALCTgetBX2DMeans","ALCT position in ALCT-L1A match window [BX]",36,0.5,36.5,20,0.5,20.5);
413  hALCTgetBX2Denominator = dbe->book2D("hALCTgetBX2Denominator","Number of ALCT Digis checked",36,0.5,36.5,20,0.5,20.5);
414  hALCTgetBX2DMeans->setAxisTitle("Chamber #");
415  hALCTgetBX2Denominator->setAxisTitle("Chamber #");
416  hALCTMatch = dbe->book1D("hALCTMatch","ALCT position in ALCT-CLCT match window [BX]",7,-0.5,6.5);
417  hALCTMatchChamberMeans = dbe->book1D("hALCTMatchChamberMeans","Chamber Mean ALCT position in ALCT-CLCT match window [BX]",60,0,6);
418  hALCTMatchSerial = dbe->book2D("hALCTMatchSerial","ALCT position in ALCT-CLCT match window [BX]",601,-0.5,600.5,7,-0.5,6.5);
419  hALCTMatchSerial->setAxisTitle("Chamber Serial Number");
420  hALCTMatch2DNumerator = dbe->book2D("hALCTMatch2DNumerator","ALCT position in ALCT-CLCT match window [BX] (sum)",36,0.5,36.5,20,0.5,20.5);
421  hALCTMatch2DMeans = dbe->book2D("hALCTMatch2DMeans","ALCT position in ALCT-CLCT match window [BX]",36,0.5,36.5,20,0.5,20.5);
422  hALCTMatch2Denominator = dbe->book2D("hALCTMatch2Denominator","Number of ALCT-CLCT matches checked",36,0.5,36.5,20,0.5,20.5);
423  hALCTMatch2DMeans->setAxisTitle("Chamber #");
424  hALCTMatch2Denominator->setAxisTitle("Chamber #");
425  hCLCTL1A = dbe->book1D("hCLCTL1A","L1A - CLCTpreTrigger at TMB [BX]",10,149.5,159.5);
426  hCLCTL1AChamberMeans = dbe->book1D("hCLCTL1AChamberMeans","Chamber Mean L1A - CLCTpreTrigger at TMB [BX]",90,150,159);
427  hCLCTL1ASerial = dbe->book2D("hCLCTL1ASerial","L1A - CLCTpreTrigger at TMB [BX]",601,-0.5,600.5,10,149.5,159.5);
428  hCLCTL1ASerial->setAxisTitle("Chamber Serial Number");
429  hCLCTL1A2DNumerator = dbe->book2D("hCLCTL1A2DNumerator","L1A - CLCTpreTrigger at TMB [BX] (sum)",36,0.5,36.5,20,0.5,20.5);
430  hCLCTL1A2DMeans = dbe->book2D("hCLCTL1A2DMeans","L1A - CLCTpreTrigger at TMB [BX]",36,0.5,36.5,20,0.5,20.5);
431  hCLCTL1A2Denominator = dbe->book2D("hCLCTL1A2Denominator","Number of TMB CLCTs checked",36,0.5,36.5,20,0.5,20.5);
432 
433 
434  // Set all Labels
460 }
MonitorElement * hEffDenominator
MonitorElement * hOSegmentsSerial
MonitorElement * hOWireSerial
MonitorElement * hSensitiveAreaEvt
MonitorElement * hOStrips
MonitorElement * hRHSTE
MonitorElement * hWireEff2
MonitorElement * book1D(const char *name, const char *title, int nchX, double lowX, double highX)
Book 1D histogram.
Definition: DQMStore.cc:954
MonitorElement * hORecHits
MonitorElement * hStripSTE2
MonitorElement * hStripReadoutEff2
MonitorElement * hRHEff
MonitorElement * hALCTMatch2DNumerator
std::vector< MonitorElement * > hRHGlobal
MonitorElement * hORecHitsSerial
void setBinLabel(int bin, const std::string &label, int axis=1)
set bin label for x, y or z axis (axis=1, 2, 3 respectively)
std::vector< MonitorElement * > hSChiSq
MonitorElement * hWirenGroupsTotal
MonitorElement * hCLCTL1ASerial
MonitorElement * hOStripSerial
MonitorElement * hSSTE2
MonitorElement * hSSTE
std::vector< MonitorElement * > hWireNumber
MonitorElement * hALCTgetBXChamberMeans
MonitorElement * hWireSTE2
MonitorElement * hALCTMatch2DMeans
MonitorElement * hSGlobalPhi
std::vector< MonitorElement * > hSnhits
MonitorElement * hOWires
MonitorElement * hSnSegments
std::vector< MonitorElement * > hRHSumQ
MonitorElement * hOStripsAndWiresAndCLCT
MonitorElement * hOSegments
std::vector< MonitorElement * > hStripPed
MonitorElement * hALCTMatchSerial
MonitorElement * hSnhitsAll
MonitorElement * hCLCTL1AChamberMeans
std::vector< MonitorElement * > hRHTiming
MonitorElement * hALCTgetBX
MonitorElement * hALCTMatch
MonitorElement * hSGlobalTheta
MonitorElement * hSTimeCombined
MonitorElement * hOWiresAndCLCT
std::vector< MonitorElement * > hRHsterr
MonitorElement * hCLCTL1A2Denominator
MonitorElement * hALCTgetBX2Denominator
MonitorElement * hSTimeVsZ
MonitorElement * hRHSTE2
MonitorElement * hALCTgetBX2DMeans
MonitorElement * hSEff2
MonitorElement * hSChiSqAll
MonitorElement * hCSCOccupancy
MonitorElement * hCLCTL1A2DNumerator
MonitorElement * hSEff
MonitorElement * hALCTgetBX2DNumerator
std::vector< MonitorElement * > hStripNumber
MonitorElement * hALCTMatch2Denominator
MonitorElement * hRHEff2
MonitorElement * hALCTMatchChamberMeans
std::vector< MonitorElement * > hWireTBin
MonitorElement * hCLCTL1A
MonitorElement * hSTimeCathode
std::vector< MonitorElement * > hRHstpos
MonitorElement * hStripNFired
std::vector< MonitorElement * > hSResid
MonitorElement * hStripEff2
MonitorElement * hALCTgetBXSerial
MonitorElement * hSTimeVsTOF
MonitorElement * hRHnrechits
MonitorElement * book2D(const char *name, const char *title, int nchX, double lowX, double highX, int nchY, double lowY, double highY)
Book 2D histogram.
Definition: DQMStore.cc:1082
std::vector< MonitorElement * > hSChiSqProb
std::vector< MonitorElement * > hRHTimingAnode
MonitorElement * hCLCTL1A2DMeans
void setAxisTitle(const std::string &title, int axis=1)
set x-, y- or z-axis title (axis=1, 2, 3 respectively)
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:667
MonitorElement * hSChiSqProbAll
std::vector< MonitorElement * > hRHRatioQ
void applyCSClabels(MonitorElement *meHisto, LabelType t, AxisType a)
int CSCOfflineMonitor::chamberSerial ( CSCDetId  id)
private

Definition at line 1896 of file CSCOfflineMonitor.cc.

Referenced by doBXMonitor(), and doOccupancies().

1896  {
1897  int st = id.station();
1898  int ri = id.ring();
1899  int ch = id.chamber();
1900  int ec = id.endcap();
1901  int kSerial = ch;
1902  if (st == 1 && ri == 1) kSerial = ch;
1903  if (st == 1 && ri == 2) kSerial = ch + 36;
1904  if (st == 1 && ri == 3) kSerial = ch + 72;
1905  if (st == 1 && ri == 4) kSerial = ch;
1906  if (st == 2 && ri == 1) kSerial = ch + 108;
1907  if (st == 2 && ri == 2) kSerial = ch + 126;
1908  if (st == 3 && ri == 1) kSerial = ch + 162;
1909  if (st == 3 && ri == 2) kSerial = ch + 180;
1910  if (st == 4 && ri == 1) kSerial = ch + 216;
1911  if (st == 4 && ri == 2) kSerial = ch + 234; // one day...
1912  if (ec == 2) kSerial = kSerial + 300;
1913  return kSerial;
1914 }
void CSCOfflineMonitor::doBXMonitor ( edm::Handle< CSCALCTDigiCollection alcts,
edm::Handle< CSCCLCTDigiCollection clcts,
const edm::Event event,
const edm::EventSetup eventSetup 
)
private

uncomment this for regional unpacking if (id!=SOME_ID) continue;

Take a reference to this FED's data

if fed has data then unpack it

get a pointer to data and pass it to constructor for unpacking

get a reference to dduData

set default detid to that for E=+z, S=1, R=1, C=1, L=1

skip the DDU if its data has serious errors define a mask for serious errors

get a reference to chamber data

first process chamber-wide digis such as LCT

default value for all digis not related to cfebs

layer=0 flags entire chamber

check alct data integrity

check tmb data integrity

Definition at line 1561 of file CSCOfflineMonitor.cc.

References CSCTMBHeader::ALCTMatchTime(), CSCTMBHeader::BXNCount(), CSCDetId::chamber(), chamberSerial(), CastorDataFrameFilter_impl::check(), CSCDCCExaminer::check(), CSCDCCExaminer::crcALCT(), CSCDCCExaminer::crcCFEB(), CSCDCCExaminer::crcTMB(), CSCDetId, FEDRawData::data(), data, CSCDCCEventData::dduData(), CSCCrateMap::detId(), CSCDetId::endcap(), CSCDCCExaminer::errors(), MonitorElement::Fill(), edm::EventSetup::get(), edm::Event::getByToken(), hALCTgetBX, hALCTgetBX2Denominator, hALCTgetBX2DNumerator, hALCTgetBXSerial, hALCTMatch, hALCTMatch2Denominator, hALCTMatch2DNumerator, hALCTMatchSerial, hCLCTL1A, hCLCTL1A2Denominator, hCLCTL1A2DNumerator, hCLCTL1ASerial, j, LogTrace, FEDNumbering::MAXCSCFEDID, FEDNumbering::MINCSCFEDID, NULL, edm::ESHandle< class >::product(), lumiPlot::rawdata, DetId::rawId(), rd_token, CSCDetId::ring(), CSCDCCExaminer::setMask(), FEDRawData::size(), CSCDetId::station(), and typeIndex().

Referenced by analyze().

1562  {
1563 
1564  // Loop over ALCTDigis
1565 
1566  for (CSCALCTDigiCollection::DigiRangeIterator j=alcts->begin(); j!=alcts->end(); j++) {
1567  const CSCDetId& idALCT = (*j).first;
1568  const CSCALCTDigiCollection::Range& range =(*j).second;
1569  for (CSCALCTDigiCollection::const_iterator digiIt = range.first; digiIt!=range.second; ++digiIt){
1570  // Valid digi in the chamber (or in neighbouring chamber)
1571  if((*digiIt).isValid()){
1572  hALCTgetBX->Fill((*digiIt).getBX());
1573  hALCTgetBXSerial->Fill(chamberSerial(idALCT),(*digiIt).getBX());
1574  hALCTgetBX2DNumerator->Fill(idALCT.chamber(),typeIndex(idALCT,2),(*digiIt).getBX());
1575  hALCTgetBX2Denominator->Fill(idALCT.chamber(),typeIndex(idALCT,2));
1576  }
1577  }
1578  }// end ALCT Digi loop
1579 
1580 
1581  // Loop over raw data to get TMBHeader information
1582  // Taking code from EventFilter/CSCRawToDigis/CSCDCCUnpacker.cc
1584  eventSetup.get<CSCCrateMapRcd>().get(hcrate);
1585  const CSCCrateMap* pcrate = hcrate.product();
1586 
1587 
1588  // Try to get raw data
1590  if ( !( event.getByToken( rd_token, rawdata ) ) ){
1591  edm::LogWarning("CSCOfflineMonitor") << " FEDRawDataColelction not available";
1592  return;
1593  }
1594 
1595 
1596 
1597  bool goodEvent = false;
1598  unsigned long dccBinCheckMask = 0x06080016;
1599  unsigned int examinerMask = 0x1FEBF3F6;
1600  unsigned int errorMask = 0x0;
1601 
1602  for (int id=FEDNumbering::MINCSCFEDID;
1603  id<=FEDNumbering::MAXCSCFEDID; ++id) { // loop over DCCs
1606 
1608  const FEDRawData& fedData = rawdata->FEDData(id);
1609  unsigned long length = fedData.size();
1610 
1611  if (length>=32){
1612  CSCDCCExaminer* examiner = NULL;
1613  std::stringstream examiner_out, examiner_err;
1614  goodEvent = true;
1615  examiner = new CSCDCCExaminer();
1616  if( examinerMask&0x40000 ) examiner->crcCFEB(1);
1617  if( examinerMask&0x8000 ) examiner->crcTMB (1);
1618  if( examinerMask&0x0400 ) examiner->crcALCT(1);
1619  examiner->setMask(examinerMask);
1620  const short unsigned int *data = (short unsigned int *)fedData.data();
1621 
1622  int res = examiner->check(data,long(fedData.size()/2));
1623  if( res < 0 ) {
1624  goodEvent=false;
1625  }
1626  else {
1627  goodEvent=!(examiner->errors()&dccBinCheckMask);
1628  }
1629 
1630 
1631  if (goodEvent) {
1633 
1634  CSCDCCExaminer * ptrExaminer = examiner;
1635  CSCDCCEventData dccData((short unsigned int *) fedData.data(), ptrExaminer);
1637  const std::vector<CSCDDUEventData> & dduData = dccData.dduData();
1638 
1640  CSCDetId layer(1, 1, 1, 1, 1);
1641  for (unsigned int iDDU=0; iDDU<dduData.size(); ++iDDU) { // loop over DDUs
1644  if (dduData[iDDU].trailer().errorstat()&errorMask) {
1645  LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "DDU# " << iDDU << " has serious error - no digis unpacked! " <<
1646  std::hex << dduData[iDDU].trailer().errorstat();
1647  continue; // to next iteration of DDU loop
1648  }
1649 
1651  const std::vector<CSCEventData> & cscData = dduData[iDDU].cscData();
1652 
1653 
1654  for (unsigned int iCSC=0; iCSC<cscData.size(); ++iCSC) { // loop over CSCs
1655 
1657  int vmecrate = cscData[iCSC].dmbHeader()->crateID();
1658  int dmb = cscData[iCSC].dmbHeader()->dmbID();
1659 
1660  int icfeb = 0;
1661  int ilayer = 0;
1662 
1663  if ((vmecrate>=1)&&(vmecrate<=60) && (dmb>=1)&&(dmb<=10)&&(dmb!=6)) {
1664  layer = pcrate->detId(vmecrate, dmb,icfeb,ilayer );
1665  }
1666  else{
1667  LogTrace ("CSCOfflineMonitor") << " detID input out of range!!! ";
1668  LogTrace ("CSCOfflineMonitor")
1669  << " skipping chamber vme= " << vmecrate << " dmb= " << dmb;
1670  continue; // to next iteration of iCSC loop
1671  }
1672 
1673 
1675  int nalct = cscData[iCSC].dmbHeader()->nalct();
1676  bool goodALCT=false;
1677  //if (nalct&&(cscData[iCSC].dataPresent>>6&0x1)==1) {
1678  if (nalct&&cscData[iCSC].alctHeader()) {
1679  if (cscData[iCSC].alctHeader()->check()){
1680  goodALCT=true;
1681  }
1682  }
1683 
1685  int nclct = cscData[iCSC].dmbHeader()->nclct();
1686  bool goodTMB=false;
1687  if (nclct&&cscData[iCSC].tmbData()) {
1688  if (cscData[iCSC].tmbHeader()->check()){
1689  if (cscData[iCSC].clctData()->check()) goodTMB=true;
1690  }
1691  }
1692 
1693  if (goodTMB && goodALCT) {
1694  const CSCTMBHeader *tmbHead = cscData[iCSC].tmbHeader();
1695  std::vector<CSCCLCTDigi> clcts = cscData[iCSC].tmbHeader()->CLCTDigis(layer.rawId());
1696  if (clcts.size()==0 || !(clcts[0].isValid()))
1697  continue;
1698  // Check if the CLCT was in ME11a (ring 4)
1699  if(layer.station()==1 && layer.ring() ==1 && clcts[0].getKeyStrip()>128){
1700  layer = CSCDetId(layer.endcap(),layer.station(),4, layer.chamber());
1701  }
1702  hALCTMatch->Fill(tmbHead->ALCTMatchTime());
1703  hALCTMatchSerial->Fill(chamberSerial(layer),tmbHead->ALCTMatchTime());
1704  // Only fill big 2D display if ALCTMatchTime !=6, since this bin is polluted by the CLCT only triggers
1705  // One will have to look at the serial plots to see if the are a lot of entries here
1706  if(tmbHead->ALCTMatchTime()!=6){
1707  hALCTMatch2DNumerator->Fill(layer.chamber(),typeIndex(layer,2),tmbHead->ALCTMatchTime());
1708  hALCTMatch2Denominator->Fill(layer.chamber(),typeIndex(layer,2));
1709  }
1710 
1711  int TMB_CLCTpre_rel_L1A = tmbHead->BXNCount()-clcts[0].getFullBX();
1712  if (TMB_CLCTpre_rel_L1A > 3563)
1713  TMB_CLCTpre_rel_L1A = TMB_CLCTpre_rel_L1A - 3564;
1714  if (TMB_CLCTpre_rel_L1A < 0)
1715  TMB_CLCTpre_rel_L1A = TMB_CLCTpre_rel_L1A + 3564;
1716 
1717  hCLCTL1A->Fill(TMB_CLCTpre_rel_L1A);
1718  hCLCTL1ASerial->Fill(chamberSerial(layer),TMB_CLCTpre_rel_L1A);
1719  hCLCTL1A2DNumerator->Fill(layer.chamber(),typeIndex(layer,2),TMB_CLCTpre_rel_L1A);
1720  hCLCTL1A2Denominator->Fill(layer.chamber(),typeIndex(layer,2));
1721 
1722  }// end if goodTMB and goodALCT
1723  }// end loop CSCData
1724  }// end loop DDU
1725  }// end if good event
1726  if (examiner!=NULL) delete examiner;
1727  }// end if non-zero fed data
1728  }// end DCC loop for NON-REFERENCE
1729 
1730  return;
1731 
1732 }
uint16_t BXNCount() const
Definition: CSCTMBHeader.h:38
01/20/05 A.Tumanov
int chamber() const
Definition: CSCDetId.h:81
void crcCFEB(bool enable)
int chamberSerial(CSCDetId id)
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:434
CSCDetId detId(int vme, int dmb, int cfeb, int layer=0) const
Definition: CSCCrateMap.cc:11
MonitorElement * hALCTMatch2DNumerator
const std::vector< CSCDDUEventData > & dduData() const
accessor to dduData
#define NULL
Definition: scimark2.h:8
MonitorElement * hCLCTL1ASerial
ExaminerStatusType errors(void) const
void crcALCT(bool enable)
size_t size() const
Lenght of the data buffer in bytes.
Definition: FEDRawData.h:47
void Fill(long long x)
edm::EDGetTokenT< FEDRawDataCollection > rd_token
MonitorElement * hALCTMatchSerial
int typeIndex(CSCDetId id, int flag=1)
bool check(const DataFrame &df, bool capcheck, bool dvercheck)
MonitorElement * hALCTgetBX
MonitorElement * hALCTMatch
void crcTMB(bool enable)
int j
Definition: DBlmapReader.cc:9
MonitorElement * hCLCTL1A2Denominator
MonitorElement * hALCTgetBX2Denominator
#define LogTrace(id)
uint16_t ALCTMatchTime() const
Definition: CSCTMBHeader.h:41
MonitorElement * hCLCTL1A2DNumerator
MonitorElement * hALCTgetBX2DNumerator
const T & get() const
Definition: EventSetup.h:55
T const * product() const
Definition: ESHandle.h:62
MonitorElement * hALCTMatch2Denominator
std::vector< CSCALCTDigi >::const_iterator const_iterator
MonitorElement * hCLCTL1A
int32_t check(const uint16_t *&buffer, int32_t length)
char data[epos_bytes_allocation]
Definition: EPOS_Wrapper.h:82
const unsigned char * data() const
Return a const pointer to the beginning of the data buffer.
Definition: FEDRawData.cc:28
std::pair< const_iterator, const_iterator > Range
MonitorElement * hALCTgetBXSerial
dictionary rawdata
Definition: lumiPlot.py:393
void setMask(ExaminerMaskType mask)
void CSCOfflineMonitor::doEfficiencies ( edm::Handle< CSCWireDigiCollection wires,
edm::Handle< CSCStripDigiCollection strips,
edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Definition at line 1261 of file CSCOfflineMonitor.cc.

References newFWLiteAna::bin, CSCDetId::chamber(), CSCChamberSpecs::chamberTypeName(), CSCDetId, diffTreeTool::diff, CSCDetId::endcap(), extrapolate1D(), MonitorElement::Fill(), first, CSCLayer::geometry(), hEffDenominator, hRHSTE, hRHSTE2, hSensitiveAreaEvt, hSSTE, hSSTE2, hStripSTE2, hWireSTE2, CSCChamber::id(), CSCChamber::layer(), CSCDetId::layer(), lineParametrization(), CSCSegment::localDirection(), CSCSegment::localPosition(), TrapezoidalPlaneBounds::parameters(), CSCDetId::ring(), CSCChamber::specs(), CSCDetId::station(), dtDQMClient_cfg::threshold, GeomDet::toGlobal(), GeomDet::toLocal(), histoStyle::weight, withinSensitiveRegion(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by analyze().

1263  {
1264 
1265  bool allWires[2][4][4][36][6];
1266  bool allStrips[2][4][4][36][6];
1267  bool AllRecHits[2][4][4][36][6];
1268  bool AllSegments[2][4][4][36];
1269 
1270  //bool MultiSegments[2][4][4][36];
1271  for(int iE = 0;iE<2;iE++){
1272  for(int iS = 0;iS<4;iS++){
1273  for(int iR = 0; iR<4;iR++){
1274  for(int iC =0;iC<36;iC++){
1275  AllSegments[iE][iS][iR][iC] = false;
1276  //MultiSegments[iE][iS][iR][iC] = false;
1277  for(int iL=0;iL<6;iL++){
1278  allWires[iE][iS][iR][iC][iL] = false;
1279  allStrips[iE][iS][iR][iC][iL] = false;
1280  AllRecHits[iE][iS][iR][iC][iL] = false;
1281  }
1282  }
1283  }
1284  }
1285  }
1286 
1287 
1288  // Wires
1289  for (CSCWireDigiCollection::DigiRangeIterator dWDiter=wires->begin(); dWDiter!=wires->end(); dWDiter++) {
1290  CSCDetId idrec = (CSCDetId)(*dWDiter).first;
1291  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
1292  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
1293  for( ; wireIter != lWire; ++wireIter) {
1294  allWires[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber() -1][idrec.layer() -1] = true;
1295  break;
1296  }
1297  }
1298 
1299  //---- STRIPS
1300  for (CSCStripDigiCollection::DigiRangeIterator dSDiter=strips->begin(); dSDiter!=strips->end(); dSDiter++) {
1301  CSCDetId idrec = (CSCDetId)(*dSDiter).first;
1302  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
1303  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
1304  for( ; stripIter != lStrip; ++stripIter) {
1305  std::vector<int> myADCVals = stripIter->getADCCounts();
1306  bool thisStripFired = false;
1307  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1308  float threshold = 13.3 ;
1309  float diff = 0.;
1310  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
1311  diff = (float)myADCVals[iCount]-thisPedestal;
1312  if (diff > threshold) {
1313  thisStripFired = true;
1314  break;
1315  }
1316  }
1317  if(thisStripFired){
1318  allStrips[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber() -1][idrec.layer() -1] = true;
1319  break;
1320  }
1321  }
1322  }
1323 
1324  // Rechits
1325  for (CSCRecHit2DCollection::const_iterator recEffIt = recHits->begin(); recEffIt != recHits->end(); recEffIt++) {
1326  //CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
1327  CSCDetId idrec = (CSCDetId)(*recEffIt).cscDetId();
1328  AllRecHits[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber() -1][idrec.layer() -1] = true;
1329 
1330  }
1331 
1332  std::vector <uint> seg_ME2(2,0) ;
1333  std::vector <uint> seg_ME3(2,0) ;
1334  std::vector < pair <CSCDetId, CSCSegment> > theSegments(4);
1335  // Segments
1336  for(CSCSegmentCollection::const_iterator segEffIt=cscSegments->begin(); segEffIt != cscSegments->end(); segEffIt++) {
1337  CSCDetId idseg = (CSCDetId)(*segEffIt).cscDetId();
1338  //if(AllSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()]){
1339  //MultiSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()] = true;
1340  //}
1341  AllSegments[idseg.endcap() -1][idseg.station() -1][idseg.ring() -1][idseg.chamber() -1] = true;
1342  // "Intrinsic" efficiency measurement relies on "good" segment extrapolation - we need the pre-selection below
1343  // station 2 "good" segment will be used for testing efficiencies in ME1 and ME3
1344  // station 3 "good" segment will be used for testing efficiencies in ME2 and ME4
1345  if(2==idseg.station() || 3==idseg.station()){
1346  uint seg_tmp ;
1347  if(2==idseg.station()){
1348  ++seg_ME2[idseg.endcap() -1];
1349  seg_tmp = seg_ME2[idseg.endcap() -1];
1350  }
1351  else{
1352  ++seg_ME3[idseg.endcap() -1];
1353  seg_tmp = seg_ME3[idseg.endcap() -1];
1354  }
1355  // is the segment good
1356  if(1== seg_tmp&& 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1357  pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1358  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1359  }
1360  }
1361  /*
1362  if(2==idseg.station()){
1363  ++seg_ME2[idseg.endcap() -1];
1364  if(1==seg_ME2[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1365  pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1366  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1367  }
1368  }
1369  else if(3==idseg.station()){
1370  ++seg_ME3[idseg.endcap() -1];
1371  if(1==seg_ME3[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1372  pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1373  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1374  }
1375  }
1376  */
1377 
1378  }
1379  // Simple efficiency calculations
1380  for(int iE = 0;iE<2;iE++){
1381  for(int iS = 0;iS<4;iS++){
1382  for(int iR = 0; iR<4;iR++){
1383  for(int iC =0;iC<36;iC++){
1384  int NumberOfLayers = 0;
1385  for(int iL=0;iL<6;iL++){
1386  if(AllRecHits[iE][iS][iR][iC][iL]){
1387  NumberOfLayers++;
1388  }
1389  }
1390  int bin = 0;
1391  if (iS==0) bin = iR+1+(iE*10);
1392  else bin = (iS+1)*2 + (iR+1) + (iE*10);
1393  if(NumberOfLayers>1){
1394  //if(!(MultiSegments[iE][iS][iR][iC])){
1395  if(AllSegments[iE][iS][iR][iC]){
1396  //---- Efficient segment evenents
1397  hSSTE->Fill(bin);
1398  }
1399  //---- All segment events (normalization)
1400  hSSTE->Fill(20+bin);
1401  //}
1402  }
1403  if(AllSegments[iE][iS][iR][iC]){
1404  if(NumberOfLayers==6){
1405  //---- Efficient rechit events
1406  hRHSTE->Fill(bin);;
1407  }
1408  //---- All rechit events (normalization)
1409  hRHSTE->Fill(20+bin);;
1410  }
1411  }
1412  }
1413  }
1414  }
1415 
1416  // pick a segment only if there are no others in the station
1417  std::vector < pair <CSCDetId, CSCSegment> * > theSeg;
1418  if(1==seg_ME2[0]) theSeg.push_back(&theSegments[0]);
1419  if(1==seg_ME3[0]) theSeg.push_back(&theSegments[1]);
1420  if(1==seg_ME2[1]) theSeg.push_back(&theSegments[2]);
1421  if(1==seg_ME3[1]) theSeg.push_back(&theSegments[3]);
1422 
1423  // Needed for plots
1424  // at the end the chamber types will be numbered as 1 to 18
1425  // (ME-4/1, -ME3/2, -ME3/1, ..., +ME3/1, +ME3/2, ME+4/1 )
1426  std::map <std::string, float> chamberTypes;
1427  chamberTypes["ME1/a"] = 0.5;
1428  chamberTypes["ME1/b"] = 1.5;
1429  chamberTypes["ME1/2"] = 2.5;
1430  chamberTypes["ME1/3"] = 3.5;
1431  chamberTypes["ME2/1"] = 4.5;
1432  chamberTypes["ME2/2"] = 5.5;
1433  chamberTypes["ME3/1"] = 6.5;
1434  chamberTypes["ME3/2"] = 7.5;
1435  chamberTypes["ME4/1"] = 8.5;
1436 
1437  if(theSeg.size()){
1438  std::map <int , GlobalPoint> extrapolatedPoint;
1439  std::map <int , GlobalPoint>::iterator it;
1440  const CSCGeometry::ChamberContainer& ChamberContainer = cscGeom->chambers();
1441  // Pick which chamber with which segment to test
1442  for(unsigned int nCh=0;nCh<ChamberContainer.size();nCh++){
1443  const CSCChamber *cscchamber = ChamberContainer[nCh];
1444  pair <CSCDetId, CSCSegment> * thisSegment = 0;
1445  for(uint iSeg =0;iSeg<theSeg.size();++iSeg ){
1446  if(cscchamber->id().endcap() == theSeg[iSeg]->first.endcap()){
1447  if(1==cscchamber->id().station() || 3==cscchamber->id().station() ){
1448  if(2==theSeg[iSeg]->first.station()){
1449  thisSegment = theSeg[iSeg];
1450  }
1451  }
1452  else if (2==cscchamber->id().station() || 4==cscchamber->id().station()){
1453  if(3==theSeg[iSeg]->first.station()){
1454  thisSegment = theSeg[iSeg];
1455  }
1456  }
1457  }
1458  }
1459  // this chamber is to be tested with thisSegment
1460  if(thisSegment){
1461  CSCSegment * seg = &(thisSegment->second);
1462  const CSCChamber *segChamber = cscGeom->chamber(thisSegment->first);
1463  LocalPoint localCenter(0.,0.,0);
1464  GlobalPoint cscchamberCenter = cscchamber->toGlobal(localCenter);
1465  // try to save some time (extrapolate a segment to a certain position only once)
1466  it = extrapolatedPoint.find(int(cscchamberCenter.z()));
1467  if(it==extrapolatedPoint.end()){
1468  GlobalPoint segPos = segChamber->toGlobal(seg->localPosition());
1469  GlobalVector segDir = segChamber->toGlobal(seg->localDirection());
1470  double paramaterLine = lineParametrization(segPos.z(),cscchamberCenter.z() , segDir.z());
1471  double xExtrapolated = extrapolate1D(segPos.x(),segDir.x(), paramaterLine);
1472  double yExtrapolated = extrapolate1D(segPos.y(),segDir.y(), paramaterLine);
1473  GlobalPoint globP (xExtrapolated, yExtrapolated, cscchamberCenter.z());
1474  extrapolatedPoint[int(cscchamberCenter.z())] = globP;
1475  }
1476  // Where does the extrapolated point lie in the (tested) chamber local frame? Here:
1477  LocalPoint extrapolatedPointLocal = cscchamber->toLocal(extrapolatedPoint[int(cscchamberCenter.z())]);
1478  const CSCLayer *layer_p = cscchamber->layer(1);//layer 1
1479  const CSCLayerGeometry *layerGeom = layer_p->geometry ();
1480  const std::array<const float, 4> & layerBounds = layerGeom->parameters ();
1481  float shiftFromEdge = 15.;//cm
1482  float shiftFromDeadZone = 10.;
1483  // is the extrapolated point within a sensitive region
1484  bool pass = withinSensitiveRegion(extrapolatedPointLocal, layerBounds,
1485  cscchamber->id().station(), cscchamber->id().ring(),
1486  shiftFromEdge, shiftFromDeadZone);
1487  if(pass){// the extrapolation point of the segment lies within sensitive region of that chamber
1488  // how many rechit layers are there in the chamber?
1489  // 0 - maybe the muon died or is deflected at large angle? do not use that case
1490  // 1 - could be noise...
1491  // 2 or more - this is promissing; this is our definition of a reliable signal; use it below
1492  // is other definition better?
1493  int nRHLayers = 0;
1494  for(int iL =0;iL<6;++iL){
1495  if(AllRecHits[cscchamber->id().endcap()-1]
1496  [cscchamber->id().station()-1]
1497  [cscchamber->id().ring()-1][cscchamber->id().chamber()-1][iL]){
1498  ++nRHLayers;
1499  }
1500  }
1501  //std::cout<<" nRHLayers = "<<nRHLayers<<std::endl;
1502  float verticalScale = chamberTypes[cscchamber->specs()->chamberTypeName()];
1503  if(cscchamberCenter.z()<0){
1504  verticalScale = - verticalScale;
1505  }
1506  verticalScale +=9.5;
1507  hSensitiveAreaEvt->Fill(float(cscchamber->id().chamber()),verticalScale);
1508  if(nRHLayers>1){// this chamber contains a reliable signal
1509  //chamberTypes[cscchamber->specs()->chamberTypeName()];
1510  // "intrinsic" efficiencies
1511  //std::cout<<" verticalScale = "<<verticalScale<<" chType = "<<cscchamber->specs()->chamberTypeName()<<std::endl;
1512  // this is the denominator forr all efficiencies
1513  hEffDenominator->Fill(float(cscchamber->id().chamber()),verticalScale);
1514  // Segment efficiency
1515  if(AllSegments[cscchamber->id().endcap()-1]
1516  [cscchamber->id().station()-1]
1517  [cscchamber->id().ring()-1][cscchamber->id().chamber()-1]){
1518  hSSTE2->Fill(float(cscchamber->id().chamber()),float(verticalScale));
1519  }
1520 
1521  for(int iL =0;iL<6;++iL){
1522  float weight = 1./6.;
1523  // one shold account for the weight in the efficiency...
1524  // Rechit efficiency
1525  if(AllRecHits[cscchamber->id().endcap()-1]
1526  [cscchamber->id().station()-1]
1527  [cscchamber->id().ring()-1][cscchamber->id().chamber()-1][iL]){
1528  hRHSTE2->Fill(float(cscchamber->id().chamber()),float(verticalScale),weight);
1529  }
1530  // Wire efficiency
1531  if(allWires[cscchamber->id().endcap()-1]
1532  [cscchamber->id().station()-1]
1533  [cscchamber->id().ring()-1][cscchamber->id().chamber()-1][iL]){
1534  // one shold account for the weight in the efficiency...
1535  hWireSTE2->Fill(float(cscchamber->id().chamber()),float(verticalScale),weight);
1536  }
1537  // Strip efficiency
1538  if(allStrips[cscchamber->id().endcap()-1]
1539  [cscchamber->id().station()-1]
1540  [cscchamber->id().ring()-1][cscchamber->id().chamber()-1][iL]){
1541  // one shold account for the weight in the efficiency...
1542  hStripSTE2->Fill(float(cscchamber->id().chamber()),float(verticalScale),weight);
1543  }
1544  }
1545  }
1546  }
1547  }
1548  }
1549  }
1550  //
1551 
1552 
1553 }
MonitorElement * hEffDenominator
int chamber() const
Definition: CSCDetId.h:81
MonitorElement * hSensitiveAreaEvt
MonitorElement * hRHSTE
virtual const std::array< const float, 4 > parameters() const
CSCDetId id() const
Get the (concrete) DetId.
Definition: CSCChamber.h:37
MonitorElement * hStripSTE2
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:47
T y() const
Definition: PV3DBase.h:63
LocalPoint toLocal(const GlobalPoint &gp) const
Conversion to the R.F. of the GeomDet.
Definition: GeomDet.h:62
MonitorElement * hSSTE2
MonitorElement * hSSTE
MonitorElement * hWireSTE2
int layer() const
Definition: CSCDetId.h:74
void Fill(long long x)
std::string chamberTypeName() const
int endcap() const
Definition: CSCDetId.h:106
LocalPoint localPosition() const
Definition: CSCSegment.h:38
LocalVector localDirection() const
Local direction.
Definition: CSCSegment.h:41
const CSCChamberSpecs * specs() const
Definition: CSCChamber.h:42
T z() const
Definition: PV3DBase.h:64
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to the given id.
Definition: CSCChamber.cc:39
bool first
Definition: L1TdeRCT.cc:75
int ring() const
Definition: CSCDetId.h:88
MonitorElement * hRHSTE2
bool withinSensitiveRegion(LocalPoint localPos, const std::array< const float, 4 > &layerBounds, int station, int ring, float shiftFromEdge, float shiftFromDeadZone)
std::vector< const CSCChamber * > ChamberContainer
Definition: CSCGeometry.h:32
int station() const
Definition: CSCDetId.h:99
int weight
Definition: histoStyle.py:50
double extrapolate1D(double initPosition, double initDirection, double parameterOfTheLine)
double lineParametrization(double z1Position, double z2Position, double z1Direction)
T x() const
Definition: PV3DBase.h:62
const CSCLayerGeometry * geometry() const
Definition: CSCLayer.h:47
void CSCOfflineMonitor::doOccupancies ( edm::Handle< CSCStripDigiCollection strips,
edm::Handle< CSCWireDigiCollection wires,
edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments,
edm::Handle< CSCCLCTDigiCollection clcts 
)
private

Definition at line 641 of file CSCOfflineMonitor.cc.

References trackerHits::c, CSCDetId::chamber(), chamberSerial(), CSCDetId, diffTreeTool::diff, alignCSCRings::e, CSCDetId::endcap(), MonitorElement::Fill(), hCSCOccupancy, hORecHits, hORecHitsSerial, hOSegments, hOSegmentsSerial, hOStrips, hOStripsAndWiresAndCLCT, hOStripSerial, hOWires, hOWiresAndCLCT, hOWireSerial, j, alignCSCRings::r, CSCDetId::ring(), alignCSCRings::s, CSCDetId::station(), dtDQMClient_cfg::threshold, and typeIndex().

Referenced by analyze().

643  {
644 
645  bool clcto[2][4][4][36];
646  bool wireo[2][4][4][36];
647  bool stripo[2][4][4][36];
648  bool rechito[2][4][4][36];
649  bool segmento[2][4][4][36];
650 
651  bool hasWires = false;
652  bool hasStrips = false;
653  bool hasRecHits = false;
654  bool hasSegments = false;
655 
656  for (int e = 0; e < 2; e++){
657  for (int s = 0; s < 4; s++){
658  for (int r = 0; r < 4; r++){
659  for (int c = 0; c < 36; c++){
660  clcto[e][s][r][c] = false;
661  wireo[e][s][r][c] = false;
662  stripo[e][s][r][c] = false;
663  rechito[e][s][r][c] = false;
664  segmento[e][s][r][c] = false;
665  }
666  }
667  }
668  }
669 
670  //clcts
671  for (CSCCLCTDigiCollection::DigiRangeIterator j=clcts->begin(); j!=clcts->end(); j++) {
672  CSCDetId id = (CSCDetId)(*j).first;
673  int kEndcap = id.endcap();
674  int kRing = id.ring();
675  int kStation = id.station();
676  int kChamber = id.chamber();
677  const CSCCLCTDigiCollection::Range& range =(*j).second;
678  for (CSCCLCTDigiCollection::const_iterator digiIt = range.first; digiIt!=range.second; ++digiIt){
679  // Valid digi in the chamber (or in neighbouring chamber)
680  if((*digiIt).isValid()){
681  //Check whether this CLCT came from ME11a
682  if( kStation ==1 && kRing==1 && (*digiIt).getKeyStrip()>128)
683  kRing = 4;
684  clcto[kEndcap-1][kStation-1][kRing-1][kChamber-1] = true;
685  }
686  }
687  }
688 
689  //wires
690  for (CSCWireDigiCollection::DigiRangeIterator wi=wires->begin(); wi!=wires->end(); wi++) {
691  CSCDetId id = (CSCDetId)(*wi).first;
692  int kEndcap = id.endcap();
693  int kRing = id.ring();
694  int kStation = id.station();
695  int kChamber = id.chamber();
696  std::vector<CSCWireDigi>::const_iterator wireIt = (*wi).second.first;
697  std::vector<CSCWireDigi>::const_iterator lastWire = (*wi).second.second;
698  for( ; wireIt != lastWire; ++wireIt){
699  if (!wireo[kEndcap-1][kStation-1][kRing-1][kChamber-1]){
700  wireo[kEndcap-1][kStation-1][kRing-1][kChamber-1] = true;
701  hOWires->Fill(kChamber,typeIndex(id,2));
703  hasWires = true;
704  if( clcto[kEndcap-1][kStation-1][kRing-1][kChamber-1])
705  hOWiresAndCLCT->Fill(kChamber,typeIndex(id,2));
706  //Also check for a CLCT in ME11a if you're in ME11 already
707  if (kStation==1 && kRing==1 && clcto[kEndcap-1][kStation-1][3][kChamber-1]){
708  CSCDetId idME11a = CSCDetId(kEndcap, kStation, 4, kChamber);
709  hOWiresAndCLCT->Fill(kChamber,typeIndex(idME11a,2));
710  }
711  }
712  }//end for loop
713  }
714 
715  //strips
716  for (CSCStripDigiCollection::DigiRangeIterator si=strips->begin(); si!=strips->end(); si++) {
717  CSCDetId id = (CSCDetId)(*si).first;
718  int kEndcap = id.endcap();
719  int kRing = id.ring();
720  int kStation = id.station();
721  int kChamber = id.chamber();
722  std::vector<CSCStripDigi>::const_iterator stripIt = (*si).second.first;
723  std::vector<CSCStripDigi>::const_iterator lastStrip = (*si).second.second;
724  for( ; stripIt != lastStrip; ++stripIt) {
725  std::vector<int> myADCVals = stripIt->getADCCounts();
726  bool thisStripFired = false;
727  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
728  float threshold = 13.3 ;
729  float diff = 0.;
730  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
731  diff = (float)myADCVals[iCount]-thisPedestal;
732  if (diff > threshold) { thisStripFired = true; }
733  }
734  if (thisStripFired) {
735  if (!stripo[kEndcap-1][kStation-1][kRing-1][kChamber-1]){
736  stripo[kEndcap-1][kStation-1][kRing-1][kChamber-1] = true;
737  hOStrips->Fill(kChamber,typeIndex(id,2));
739  hasStrips = true;
740  if (clcto[kEndcap-1][kStation-1][kRing-1][kChamber-1]){
741  // check if there is a wire digi in this chamber too
742  // for ME 1/4 check for a wire in ME 1/1
743  if(wireo[kEndcap-1][kStation-1][kRing-1][kChamber-1] || (kRing==4 && wireo[kEndcap-1][kStation-1][0][kChamber-1]) ){
744  hOStripsAndWiresAndCLCT->Fill(kChamber,typeIndex(id,2));
745  }
746  }//end clct and wire digi check
747  }
748  }//end if (thisStripFired)
749  }
750  }
751 
752  //rechits
754  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
755  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
756  int kEndcap = idrec.endcap();
757  int kRing = idrec.ring();
758  int kStation = idrec.station();
759  int kChamber = idrec.chamber();
760  if (!rechito[kEndcap-1][kStation-1][kRing-1][kChamber-1]){
761  rechito[kEndcap-1][kStation-1][kRing-1][kChamber-1] = true;
763  hORecHits->Fill(kChamber,typeIndex(idrec,2));
764  hasRecHits = true;
765  }
766  }
767 
768  //segments
769  for(CSCSegmentCollection::const_iterator segIt=cscSegments->begin(); segIt != cscSegments->end(); segIt++) {
770  CSCDetId id = (CSCDetId)(*segIt).cscDetId();
771  int kEndcap = id.endcap();
772  int kRing = id.ring();
773  int kStation = id.station();
774  int kChamber = id.chamber();
775  if (!segmento[kEndcap-1][kStation-1][kRing-1][kChamber-1]){
776  segmento[kEndcap-1][kStation-1][kRing-1][kChamber-1] = true;
778  hOSegments->Fill(kChamber,typeIndex(id,2));
779  hasSegments = true;
780  }
781  }
782 
783  //Overall CSC Occupancy
784  hCSCOccupancy->Fill(1);
785  if (hasWires) hCSCOccupancy->Fill(3);
786  if (hasStrips) hCSCOccupancy->Fill(5);
787  if (hasWires && hasStrips) hCSCOccupancy->Fill(7);
788  if (hasRecHits) hCSCOccupancy->Fill(9);
789  if (hasSegments) hCSCOccupancy->Fill(11);
790 
791 
792  }
MonitorElement * hOSegmentsSerial
int chamber() const
Definition: CSCDetId.h:81
MonitorElement * hOWireSerial
MonitorElement * hOStrips
int chamberSerial(CSCDetId id)
MonitorElement * hORecHits
MonitorElement * hORecHitsSerial
MonitorElement * hOStripSerial
void Fill(long long x)
MonitorElement * hOWires
int endcap() const
Definition: CSCDetId.h:106
MonitorElement * hOStripsAndWiresAndCLCT
MonitorElement * hOSegments
int typeIndex(CSCDetId id, int flag=1)
int j
Definition: DBlmapReader.cc:9
MonitorElement * hOWiresAndCLCT
int ring() const
Definition: CSCDetId.h:88
MonitorElement * hCSCOccupancy
std::vector< CSCCLCTDigi >::const_iterator const_iterator
int station() const
Definition: CSCDetId.h:99
std::pair< const_iterator, const_iterator > Range
void CSCOfflineMonitor::doPedestalNoise ( edm::Handle< CSCStripDigiCollection strips)
private

Definition at line 869 of file CSCOfflineMonitor.cc.

References CSCDetId, getSignal(), hStripPed, CSCDetId::station(), dtDQMClient_cfg::threshold, and typeIndex().

Referenced by analyze().

869  {
870 
871  for (CSCStripDigiCollection::DigiRangeIterator dPNiter=strips->begin(); dPNiter!=strips->end(); dPNiter++) {
872  CSCDetId id = (CSCDetId)(*dPNiter).first;
873  int kStation = id.station();
874  int kRing = id.ring();
875  std::vector<CSCStripDigi>::const_iterator pedIt = (*dPNiter).second.first;
876  std::vector<CSCStripDigi>::const_iterator lStrip = (*dPNiter).second.second;
877  for( ; pedIt != lStrip; ++pedIt) {
878  int myStrip = pedIt->getStrip();
879  std::vector<int> myADCVals = pedIt->getADCCounts();
880  float TotalADC = getSignal(*strips, id, myStrip);
881  bool thisStripFired = false;
882  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
883  float thisSignal = (1./6)*(myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
884  float threshold = 13.3;
885  if(kStation == 1 && kRing == 4)
886  {
887  kRing = 1;
888  if(myStrip <= 16) myStrip += 64; // no trapping for any bizarreness
889  }
890  if (TotalADC > threshold) { thisStripFired = true;}
891  if (!thisStripFired){
892  float ADC = thisSignal - thisPedestal;
893  hStripPed[typeIndex(id)-1]->Fill(ADC);
894  }
895  }
896  }
897 
898 }
float getSignal(const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
std::vector< MonitorElement * > hStripPed
int typeIndex(CSCDetId id, int flag=1)
int station() const
Definition: CSCDetId.h:99
void CSCOfflineMonitor::doRecHits ( edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCStripDigiCollection strips,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Find the charge associated with this hit

Definition at line 907 of file CSCOfflineMonitor.cc.

References CSCDetId, CSCDetId::endcap(), MonitorElement::Fill(), hRHGlobal, hRHnrechits, hRHRatioQ, hRHsterr, hRHstpos, hRHSumQ, hRHTiming, hRHTimingAnode, i, j, CSCDetId::station(), GeomDet::toGlobal(), typeIndex(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by analyze().

909  {
910 
911  // Get the RecHits collection :
912  int nRecHits = recHits->size();
913 
914  // ---------------------
915  // Loop over rechits
916  // ---------------------
917  // Build iterator for rechits and loop :
919  for (dRHIter = recHits->begin(); dRHIter != recHits->end(); dRHIter++) {
920 
921  // Find chamber with rechits in CSC
922  CSCDetId idrec = (CSCDetId)(*dRHIter).cscDetId();
923 
924  // Store rechit as a Local Point:
925  LocalPoint rhitlocal = (*dRHIter).localPosition();
926  //float xreco = rhitlocal.x();
927  //float yreco = rhitlocal.y();
928 
929  // Get the reconstucted strip position and error
930  float stpos = (*dRHIter).positionWithinStrip();
931  float sterr = (*dRHIter).errorWithinStrip();
932 
934 
935  int adcsize = dRHIter->nStrips()*dRHIter->nTimeBins();
936  float rHSumQ = 0;
937  float sumsides = 0;
938  for (unsigned int i = 0; i < dRHIter->nStrips(); i++){
939  for (unsigned int j=0; j<dRHIter->nTimeBins()-1; j++) {
940  rHSumQ+=dRHIter->adcs(i,j);
941  if ( i != 1 ) sumsides += dRHIter->adcs(i,j); // skip central strip
942  }
943  }
944 
945  float rHratioQ = sumsides/rHSumQ;
946  if (adcsize != 12) rHratioQ = -99;
947 
948  // Get the signal timing of this hit
949  float rHtime = (*dRHIter).tpeak(); //calculated from cathode SCA bins
950  float rHtimeAnode = (*dRHIter).wireTime(); // calculated from anode wire bx
951 
952  // Get pointer to the layer:
953  const CSCLayer* csclayer = cscGeom->layer( idrec );
954 
955  // Transform hit position from local chamber geometry to global CMS geom
956  GlobalPoint rhitglobal= csclayer->toGlobal(rhitlocal);
957  float grecx = rhitglobal.x();
958  float grecy = rhitglobal.y();
959 
960  // Fill some histograms
961  int sIndex = idrec.station() + ((idrec.endcap()-1) * 4);
962  int tIndex = typeIndex(idrec);
963  hRHSumQ[tIndex-1]->Fill(rHSumQ);
964  hRHRatioQ[tIndex-1]->Fill(rHratioQ);
965  hRHstpos[tIndex-1]->Fill(stpos);
966  hRHsterr[tIndex-1]->Fill(sterr);
967  hRHTiming[tIndex-1]->Fill(rHtime);
968  hRHTimingAnode[tIndex-1]->Fill(rHtimeAnode);
969  hRHGlobal[sIndex-1]->Fill(grecx,grecy);
970 
971  } //end rechit loop
972 
973  if (nRecHits == 0) nRecHits = -1;
974  hRHnrechits->Fill(nRecHits);
975 
976 }
int i
Definition: DBlmapReader.cc:9
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:47
std::vector< MonitorElement * > hRHGlobal
T y() const
Definition: PV3DBase.h:63
void Fill(long long x)
int endcap() const
Definition: CSCDetId.h:106
std::vector< MonitorElement * > hRHSumQ
int typeIndex(CSCDetId id, int flag=1)
std::vector< MonitorElement * > hRHTiming
int j
Definition: DBlmapReader.cc:9
std::vector< MonitorElement * > hRHsterr
std::vector< MonitorElement * > hRHstpos
int station() const
Definition: CSCDetId.h:99
MonitorElement * hRHnrechits
std::vector< MonitorElement * > hRHTimingAnode
T x() const
Definition: PV3DBase.h:62
std::vector< MonitorElement * > hRHRatioQ
void CSCOfflineMonitor::doResolution ( edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Find the strip containing this hit

Definition at line 1097 of file CSCOfflineMonitor.cc.

References CSCDetId, fitX(), hSResid, kLayer(), CSCDetId::layer(), CSCDetId::ring(), CSCDetId::station(), and typeIndex().

Referenced by analyze().

1098  {
1099 
1100  for(CSCSegmentCollection::const_iterator dSiter=cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1101  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1102  //
1103  // try to get the CSC recHits that contribute to this segment.
1104  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1105  int nRH = (*dSiter).nRecHits();
1106  int jRH = 0;
1107  CLHEP::HepMatrix sp(6,1);
1108  CLHEP::HepMatrix se(6,1);
1109  for ( vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1110  jRH++;
1111  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
1112  //int kEndcap = idRH.endcap();
1113  int kRing = idRH.ring();
1114  int kStation = idRH.station();
1115  //int kChamber = idRH.chamber();
1116  int kLayer = idRH.layer();
1117 
1119  int centerid = iRH->nStrips()/2 + 1;
1120  int centerStrip = iRH->channels(centerid - 1);
1121 
1122  // If this segment has 6 hits, find the position of each hit on the strip in units of stripwidth and store values
1123  if (nRH == 6){
1124  float stpos = (*iRH).positionWithinStrip();
1125  se(kLayer,1) = (*iRH).errorWithinStrip();
1126  // Take into account half-strip staggering of layers (ME1/1 has no staggering)
1127  if (kStation == 1 && (kRing == 1 || kRing == 4)) sp(kLayer,1) = stpos + centerStrip;
1128  else{
1129  if (kLayer == 1 || kLayer == 3 || kLayer == 5) sp(kLayer,1) = stpos + centerStrip;
1130  if (kLayer == 2 || kLayer == 4 || kLayer == 6) sp(kLayer,1) = stpos - 0.5 + centerStrip;
1131  }
1132  }
1133 
1134  }
1135 
1136  float residual = -99;
1137  // Fit all points except layer 3, then compare expected value for layer 3 to reconstructed value
1138  if (nRH == 6){
1139  float expected = fitX(sp,se);
1140  residual = expected - sp(3,1);
1141  }
1142 
1143  hSResid[typeIndex(id)-1]->Fill(residual);
1144 
1145  } // end segment loop
1146 
1147 
1148 
1149 }
int layer() const
Definition: CSCDetId.h:74
int typeIndex(CSCDetId id, int flag=1)
float fitX(const CLHEP::HepMatrix &sp, const CLHEP::HepMatrix &ep)
static const std::string kLayer("layer")
int ring() const
Definition: CSCDetId.h:88
std::vector< MonitorElement * > hSResid
int station() const
Definition: CSCDetId.h:99
void CSCOfflineMonitor::doSegments ( edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Definition at line 985 of file CSCOfflineMonitor.cc.

References ChiSquaredProbability(), CSCDetId, MonitorElement::Fill(), hSChiSq, hSChiSqAll, hSChiSqProb, hSChiSqProbAll, hSGlobalPhi, hSGlobalTheta, hSnhits, hSnhitsAll, hSnSegments, hSTimeCathode, hSTimeCombined, hSTimeVsTOF, hSTimeVsZ, i, j, PV3DBase< T, PVType, FrameType >::phi(), mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::theta(), GeomDet::toGlobal(), typeIndex(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by analyze().

986  {
987 
988  // get CSC segment collection
989  int nSegments = cscSegments->size();
990 
991  for(CSCSegmentCollection::const_iterator dSiter=cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
992  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
993  float chisq = (*dSiter).chi2();
994  int nhits = (*dSiter).nRecHits();
995  int nDOF = 2*nhits-4;
996  float nChi2 = chisq/nDOF;
997  double chisqProb = ChiSquaredProbability( (double)chisq, nDOF );
998  LocalPoint localPos = (*dSiter).localPosition();
999  LocalVector segDir = (*dSiter).localDirection();
1000 
1001  // prepare to calculate segment times
1002  float timeCathode = 0; //average from cathode information alone
1003  float timeAnode = 0; //average from pruned anode information alone
1004  float timeCombined = 0; //average from cathode hits and pruned anode list
1005  std::vector<float> cathodeTimes;
1006  std::vector<float> anodeTimes;
1007  // Get the CSC recHits that contribute to this segment.
1008  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1009  for ( vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1010  if ( !((*iRH).isValid()) ) continue; // only interested in valid hits
1011  cathodeTimes.push_back((*iRH).tpeak());
1012  anodeTimes.push_back((*iRH).wireTime());
1013  }//end rechit loop
1014 
1015  // Calculate cathode average
1016  for (unsigned int i=0; i<cathodeTimes.size(); i++)
1017  timeCathode+=cathodeTimes[i]/cathodeTimes.size();
1018 
1019  // Prune the anode list to deal with the late tail
1020  float anodeMaxDiff;
1021  bool modified = false;
1022  std::vector<float>::iterator anodeMaxHit;
1023  do {
1024  if (anodeTimes.size()==0) continue;
1025  timeAnode=0;
1026  anodeMaxDiff=0;
1027  modified=false;
1028 
1029  // Find the average
1030  for (unsigned int j=0; j<anodeTimes.size(); j++) timeAnode+=anodeTimes[j]/anodeTimes.size();
1031 
1032  // Find the maximum outlier hit
1033  for (unsigned int j=0; j<anodeTimes.size(); j++) {
1034  if (fabs(anodeTimes[j]-timeAnode)>anodeMaxDiff) {
1035  anodeMaxHit=anodeTimes.begin()+j;
1036  anodeMaxDiff=fabs(anodeTimes[j]-timeAnode);
1037  }
1038  }
1039 
1040  // Cut hit if its greater than some time away
1041  if (anodeMaxDiff>26) {
1042  modified=true;
1043  anodeTimes.erase(anodeMaxHit);
1044  }
1045  } while (modified);
1046 
1047  // Calculate combined anode and cathode time average
1048  if(cathodeTimes.size()+anodeTimes.size() >0 )
1049  timeCombined = (timeCathode*cathodeTimes.size() + timeAnode*anodeTimes.size())/(cathodeTimes.size()+anodeTimes.size());
1050 
1051  // global transformation
1052  float globX = 0.;
1053  float globY = 0.;
1054  float globZ = 0.;
1055  float globTOF = 0.;
1056  float globTheta = 0.;
1057  float globPhi = 0.;
1058  const CSCChamber* cscchamber = cscGeom->chamber(id);
1059  if (cscchamber) {
1060  GlobalPoint globalPosition = cscchamber->toGlobal(localPos);
1061  globX = globalPosition.x();
1062  globY = globalPosition.y();
1063  globZ = globalPosition.z();
1064  globTOF = sqrt(globX*globX+globY*globY+globZ*globZ);
1065  GlobalVector globalDirection = cscchamber->toGlobal(segDir);
1066  globTheta = globalDirection.theta();
1067  globPhi = globalDirection.phi();
1068  }
1069 
1070  // Fill histos
1071  int tIndex = typeIndex(id);
1072  hSnhitsAll->Fill(nhits);
1073  hSnhits[tIndex-1]->Fill(nhits);
1074  hSChiSqAll->Fill(nChi2);
1075  hSChiSq[tIndex-1]->Fill(nChi2);
1076  hSChiSqProbAll->Fill(chisqProb);
1077  hSChiSqProb[tIndex-1]->Fill(chisqProb);
1078  hSGlobalTheta->Fill(globTheta);
1079  hSGlobalPhi->Fill(globPhi);
1080  hSTimeCathode->Fill(timeCathode);
1081  hSTimeCombined->Fill(timeCombined);
1082  hSTimeVsZ->Fill(globZ, timeCombined);
1083  hSTimeVsTOF->Fill(globTOF, timeCombined);
1084 
1085  } // end segment loop
1086 
1087  if (nSegments == 0) nSegments = -1;
1088  hSnSegments->Fill(nSegments);
1089 
1090 }
int i
Definition: DBlmapReader.cc:9
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:47
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
T y() const
Definition: PV3DBase.h:63
std::vector< MonitorElement * > hSChiSq
MonitorElement * hSGlobalPhi
void Fill(long long x)
std::vector< MonitorElement * > hSnhits
Geom::Theta< T > theta() const
Definition: PV3DBase.h:75
MonitorElement * hSnSegments
int typeIndex(CSCDetId id, int flag=1)
MonitorElement * hSnhitsAll
T sqrt(T t)
Definition: SSEVec.h:48
T z() const
Definition: PV3DBase.h:64
MonitorElement * hSGlobalTheta
int j
Definition: DBlmapReader.cc:9
float ChiSquaredProbability(double chiSquared, double nrDOF)
MonitorElement * hSTimeCombined
MonitorElement * hSTimeVsZ
MonitorElement * hSChiSqAll
MonitorElement * hSTimeCathode
MonitorElement * hSTimeVsTOF
std::vector< MonitorElement * > hSChiSqProb
T x() const
Definition: PV3DBase.h:62
MonitorElement * hSChiSqProbAll
void CSCOfflineMonitor::doStripDigis ( edm::Handle< CSCStripDigiCollection strips)
private

Definition at line 830 of file CSCOfflineMonitor.cc.

References CSCDetId, diffTreeTool::diff, MonitorElement::Fill(), hStripNFired, hStripNumber, dtDQMClient_cfg::threshold, and typeIndex().

Referenced by analyze().

830  {
831 
832  int nStripsFired = 0;
833  for (CSCStripDigiCollection::DigiRangeIterator dSDiter=strips->begin(); dSDiter!=strips->end(); dSDiter++) {
834  CSCDetId id = (CSCDetId)(*dSDiter).first;
835  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
836  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
837  for( ; stripIter != lStrip; ++stripIter) {
838  int myStrip = stripIter->getStrip();
839  std::vector<int> myADCVals = stripIter->getADCCounts();
840  bool thisStripFired = false;
841  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
842  float threshold = 13.3 ;
843  float diff = 0.;
844  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
845  diff = (float)myADCVals[iCount]-thisPedestal;
846  if (diff > threshold) { thisStripFired = true; }
847  }
848  if (thisStripFired) {
849  nStripsFired++;
850  hStripNumber[typeIndex(id)-1]->Fill(myStrip);
851  }
852  }
853  } // end strip loop
854 
855  // this way you can zero suppress but still store info on # events with no digis
856  if (nStripsFired == 0) nStripsFired = -1;
857  hStripNFired->Fill(nStripsFired);
858  // fill n per event
859 
860 }
void Fill(long long x)
int typeIndex(CSCDetId id, int flag=1)
std::vector< MonitorElement * > hStripNumber
MonitorElement * hStripNFired
void CSCOfflineMonitor::doWireDigis ( edm::Handle< CSCWireDigiCollection wires)
private

Definition at line 801 of file CSCOfflineMonitor.cc.

References CSCDetId, MonitorElement::Fill(), hWirenGroupsTotal, hWireNumber, hWireTBin, and typeIndex().

Referenced by analyze().

801  {
802 
803  int nWireGroupsTotal = 0;
804  for (CSCWireDigiCollection::DigiRangeIterator dWDiter=wires->begin(); dWDiter!=wires->end(); dWDiter++) {
805  CSCDetId id = (CSCDetId)(*dWDiter).first;
806  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
807  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
808  for( ; wireIter != lWire; ++wireIter) {
809  int myWire = wireIter->getWireGroup();
810  int myTBin = wireIter->getTimeBin();
811  nWireGroupsTotal++;
812  hWireTBin[typeIndex(id)-1]->Fill(myTBin);
813  hWireNumber[typeIndex(id)-1]->Fill(myWire);
814  }
815  } // end wire loop
816 
817  // this way you can zero suppress but still store info on # events with no digis
818  if (nWireGroupsTotal == 0) nWireGroupsTotal = -1;
819  hWirenGroupsTotal->Fill(nWireGroupsTotal);
820 
821 }
MonitorElement * hWirenGroupsTotal
std::vector< MonitorElement * > hWireNumber
void Fill(long long x)
int typeIndex(CSCDetId id, int flag=1)
std::vector< MonitorElement * > hWireTBin
void CSCOfflineMonitor::endJob ( void  )
virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 472 of file CSCOfflineMonitor.cc.

References dbe, finalize(), finalizedHistograms_, edm::ParameterSet::getParameter(), dumpDBToFile_GT_ttrig_cfg::outputFileName, param, DQMStore::save(), and funct::true.

472  {
473  if(nullptr == dbe) {
474  return;
475  }
476  finalize() ;
478 
479  bool saveHistos = param.getParameter<bool>("saveHistos");
480  string outputFileName = param.getParameter<string>("outputFileName");
481  if(saveHistos){
482  dbe->save(outputFileName);
483  }
484 
485 }
T getParameter(std::string const &) const
edm::ParameterSet param
void save(const std::string &filename, const std::string &path="", const std::string &pattern="", const std::string &rewrite="", const uint32_t run=0, const uint32_t lumi=0, SaveReferenceTag ref=SaveWithReference, int minStatus=dqm::qstatus::STATUS_OK, const std::string &fileupdate="RECREATE", const bool resetMEsAfterWriting=false)
Definition: DQMStore.cc:2540
void CSCOfflineMonitor::endRun ( edm::Run const &  ,
edm::EventSetup const &   
)
virtual

Reimplemented from edm::EDAnalyzer.

Definition at line 463 of file CSCOfflineMonitor.cc.

References finalize(), finalizedHistograms_, and funct::true.

463  {
464 
465  if (!finalizedHistograms_){
466  finalize() ;
468  }
469 
470 }
double CSCOfflineMonitor::extrapolate1D ( double  initPosition,
double  initDirection,
double  parameterOfTheLine 
)
inlineprivate

Definition at line 134 of file CSCOfflineMonitor.h.

Referenced by doEfficiencies().

134  {
135  double extrapolatedPosition = initPosition + initDirection*parameterOfTheLine;
136  return extrapolatedPosition;
137  }
void CSCOfflineMonitor::fillEfficiencyHistos ( int  bin,
int  flag 
)
private
void CSCOfflineMonitor::finalize ( void  )

Definition at line 488 of file CSCOfflineMonitor.cc.

References dbe, DQMStore::get(), MonitorElement::getTH1F(), MonitorElement::getTH2F(), hALCTgetBX2Denominator, hALCTgetBX2DMeans, hALCTgetBX2DNumerator, hALCTgetBXChamberMeans, hALCTgetBXSerial, hALCTMatch2Denominator, hALCTMatch2DMeans, hALCTMatch2DNumerator, hALCTMatchChamberMeans, hALCTMatchSerial, harvestChamberMeans(), hCLCTL1A2Denominator, hCLCTL1A2DMeans, hCLCTL1A2DNumerator, hCLCTL1AChamberMeans, hCLCTL1ASerial, hEffDenominator, histoEfficiency(), hOStripsAndWiresAndCLCT, hOWiresAndCLCT, hRHEff, hRHEff2, hRHSTE, hRHSTE2, hSEff, hSEff2, hSSTE, hSSTE2, hStripEff2, hStripReadoutEff2, hStripSTE2, hWireEff2, hWireSTE2, and normalize().

Referenced by endJob(), and endRun().

488  {
489 
490  hRHEff = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hRHEff");
491  hSEff = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hSEff");
492  hSEff2 = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hSEff2");
493  hRHEff2 = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hRHEff2");
494  hStripEff2 = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hStripEff2");
495  hWireEff2 = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hWireEff2");
496 
497  hOStripsAndWiresAndCLCT= dbe->get("CSC/CSCOfflineMonitor/Occupancy/hOStripsAndWiresAndCLCT");
498  hOWiresAndCLCT= dbe->get("CSC/CSCOfflineMonitor/Occupancy/hOWiresAndCLCT");
499  hStripReadoutEff2 = dbe->get("CSC/CSCOfflineMonitor/Efficiency/hStripReadoutEff2");
500 
501  hALCTgetBX2DMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTgetBX2DMeans");
502  hALCTMatch2DMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTMatch2DMeans");
503  hCLCTL1A2DMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hCLCTL1A2DMeans");
504 
505  hALCTgetBXSerial = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTgetBXSerial");
506  hALCTMatchSerial = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTMatchSerial");
507  hCLCTL1ASerial = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hCLCTL1ASerial");
508 
509  hALCTgetBXChamberMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTgetBXChamberMeans");
510  hALCTMatchChamberMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hALCTMatchChamberMeans");
511  hCLCTL1AChamberMeans = dbe->get("CSC/CSCOfflineMonitor/BXMonitor/hCLCTL1AChamberMeans");
512 
515  if (hSEff2) hSEff2->getTH2F()->Divide(hSSTE2->getTH2F(),\
516  hEffDenominator->getTH2F(), 1., 1.,"B");
517  if (hRHEff2) hRHEff2->getTH2F()->Divide(hRHSTE2->getTH2F(),\
518  hEffDenominator->getTH2F(), 1., 1., "B");
519  if (hStripEff2) hStripEff2->getTH2F()->Divide(hStripSTE2->getTH2F(),\
520  hEffDenominator->getTH2F(), 1., 1., "B");
521  if (hWireEff2) hWireEff2->getTH2F()->Divide(hWireSTE2->getTH2F(),\
522  hEffDenominator->getTH2F(), 1., 1., "B");
524  hOWiresAndCLCT->getTH2F(), 1., 1., "B");
525  if (hALCTMatch2DMeans){
530  }
531  if (hALCTgetBX2DMeans) {
536  }
537  if (hCLCTL1A2DMeans) {
542  }
543 
547 
548 
549 }
MonitorElement * hEffDenominator
void harvestChamberMeans(MonitorElement *meMean1D, MonitorElement *meMean2D, MonitorElement *hNum, MonitorElement *meDenom)
MonitorElement * hRHSTE
MonitorElement * hWireEff2
MonitorElement * hStripSTE2
void histoEfficiency(TH1F *readHisto, MonitorElement *writeHisto)
MonitorElement * hStripReadoutEff2
MonitorElement * hRHEff
MonitorElement * hALCTMatch2DNumerator
MonitorElement * hCLCTL1ASerial
MonitorElement * hSSTE2
MonitorElement * hSSTE
MonitorElement * hALCTgetBXChamberMeans
MonitorElement * hWireSTE2
MonitorElement * hALCTMatch2DMeans
MonitorElement * hOStripsAndWiresAndCLCT
void normalize(MonitorElement *me)
MonitorElement * hALCTMatchSerial
MonitorElement * hCLCTL1AChamberMeans
MonitorElement * hOWiresAndCLCT
MonitorElement * hCLCTL1A2Denominator
MonitorElement * get(const std::string &path) const
get ME from full pathname (e.g. &quot;my/long/dir/my_histo&quot;)
Definition: DQMStore.cc:1708
MonitorElement * hALCTgetBX2Denominator
MonitorElement * hRHSTE2
MonitorElement * hALCTgetBX2DMeans
MonitorElement * hSEff2
MonitorElement * hCLCTL1A2DNumerator
MonitorElement * hSEff
MonitorElement * hALCTgetBX2DNumerator
MonitorElement * hALCTMatch2Denominator
TH1F * getTH1F(void) const
MonitorElement * hRHEff2
MonitorElement * hALCTMatchChamberMeans
MonitorElement * hStripEff2
MonitorElement * hALCTgetBXSerial
TH2F * getTH2F(void) const
MonitorElement * hCLCTL1A2DMeans
float CSCOfflineMonitor::fitX ( const CLHEP::HepMatrix &  sp,
const CLHEP::HepMatrix &  ep 
)
private

Definition at line 1157 of file CSCOfflineMonitor.cc.

References delta, benchmark_cfg::errors, i, S(), and slope.

Referenced by doResolution().

1157  {
1158 
1159  float S = 0;
1160  float Sx = 0;
1161  float Sy = 0;
1162  float Sxx = 0;
1163  float Sxy = 0;
1164  float sigma2 = 0;
1165 
1166  for (int i=1;i<7;i++){
1167  if (i != 3){
1168  sigma2 = errors(i,1)*errors(i,1);
1169  S = S + (1/sigma2);
1170  Sy = Sy + (points(i,1)/sigma2);
1171  Sx = Sx + ((i)/sigma2);
1172  Sxx = Sxx + (i*i)/sigma2;
1173  Sxy = Sxy + (((i)*points(i,1))/sigma2);
1174  }
1175  }
1176 
1177  float delta = S*Sxx - Sx*Sx;
1178  float intercept = (Sxx*Sy - Sx*Sxy)/delta;
1179  float slope = (S*Sxy - Sx*Sy)/delta;
1180 
1181  return (intercept + slope*3);
1182 
1183 }
dbl * delta
Definition: mlp_gen.cc:36
int i
Definition: DBlmapReader.cc:9
static const double slope[3]
double S(const TLorentzVector &, const TLorentzVector &)
Definition: Particle.cc:99
void CSCOfflineMonitor::getEfficiency ( float  bin,
float  Norm,
std::vector< float > &  eff 
)
private

Definition at line 1736 of file CSCOfflineMonitor.cc.

References mathSSE::sqrt().

Referenced by histoEfficiency().

1736  {
1737  //---- Efficiency with binomial error
1738  float Efficiency = 0.;
1739  float EffError = 0.;
1740  if(fabs(Norm)>0.000000001){
1741  Efficiency = bin/Norm;
1742  if(bin<Norm){
1743  EffError = sqrt( (1.-Efficiency)*Efficiency/Norm );
1744  }
1745  }
1746  eff[0] = Efficiency;
1747  eff[1] = EffError;
1748 }
T sqrt(T t)
Definition: SSEVec.h:48
float CSCOfflineMonitor::getSignal ( const CSCStripDigiCollection stripdigis,
CSCDetId  idRH,
int  centerStrip 
)
private

Definition at line 1192 of file CSCOfflineMonitor.cc.

References CSCDetId, if(), and prof2calltree::last.

Referenced by doPedestalNoise().

1193  {
1194 
1195  float SigADC[5];
1196  float TotalADC = 0;
1197  SigADC[0] = 0;
1198  SigADC[1] = 0;
1199  SigADC[2] = 0;
1200  SigADC[3] = 0;
1201  SigADC[4] = 0;
1202 
1203 
1204  // Loop over strip digis
1206 
1207  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++){
1208  CSCDetId id = (CSCDetId)(*sIt).first;
1209  if (id == idCS){
1210 
1211  // First, find the Signal-Pedestal for center strip
1212  vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
1213  vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
1214  for ( ; digiItr != last; ++digiItr ) {
1215  int thisStrip = digiItr->getStrip();
1216  if (thisStrip == (centerStrip)){
1217  std::vector<int> myADCVals = digiItr->getADCCounts();
1218  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1219  float thisSignal = (myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
1220  SigADC[0] = thisSignal - 6*thisPedestal;
1221  }
1222  // Now,find the Signal-Pedestal for neighbouring 4 strips
1223  if (thisStrip == (centerStrip+1)){
1224  std::vector<int> myADCVals = digiItr->getADCCounts();
1225  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1226  float thisSignal = (myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
1227  SigADC[1] = thisSignal - 6*thisPedestal;
1228  }
1229  if (thisStrip == (centerStrip+2)){
1230  std::vector<int> myADCVals = digiItr->getADCCounts();
1231  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1232  float thisSignal = (myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
1233  SigADC[2] = thisSignal - 6*thisPedestal;
1234  }
1235  if (thisStrip == (centerStrip-1)){
1236  std::vector<int> myADCVals = digiItr->getADCCounts();
1237  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1238  float thisSignal = (myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
1239  SigADC[3] = thisSignal - 6*thisPedestal;
1240  }
1241  if (thisStrip == (centerStrip-2)){
1242  std::vector<int> myADCVals = digiItr->getADCCounts();
1243  float thisPedestal = 0.5*(float)(myADCVals[0]+myADCVals[1]);
1244  float thisSignal = (myADCVals[2]+myADCVals[3]+myADCVals[4]+myADCVals[5]+myADCVals[6]+myADCVals[7]);
1245  SigADC[4] = thisSignal - 6*thisPedestal;
1246  }
1247  }
1248  TotalADC = 0.2*(SigADC[0]+SigADC[1]+SigADC[2]+SigADC[3]+SigADC[4]);
1249  }
1250  }
1251  return TotalADC;
1252 }
if(conf.exists("allCellsPositionCalc"))
void CSCOfflineMonitor::harvestChamberMeans ( MonitorElement meMean1D,
MonitorElement meMean2D,
MonitorElement hNum,
MonitorElement meDenom 
)
private

Definition at line 551 of file CSCOfflineMonitor.cc.

References MonitorElement::Fill(), MonitorElement::getBinContent(), MonitorElement::getNbinsX(), MonitorElement::getNbinsY(), timingPdfMaker::mean, and MonitorElement::setBinContent().

Referenced by finalize().

554  {
555 
556 
557  if (hNum->getNbinsY()!= meDenom->getNbinsY() || hNum->getNbinsX()!= meDenom->getNbinsX())
558  return;
559  if (meMean2D->getNbinsY()!= meDenom->getNbinsY() || meMean2D->getNbinsX()!= meDenom->getNbinsX())
560  return;
561 
562  float mean;
563  for (int biny = 0; biny < hNum->getNbinsY()+1 ; biny++){
564  for (int binx = 0; binx < hNum->getNbinsX()+1 ; binx++){
565  if ( meDenom->getBinContent(binx,biny) > 0){
566  mean = hNum->getBinContent(binx,biny)/meDenom->getBinContent(binx,biny);
567  meMean1D->Fill(mean);
568  meMean2D->setBinContent(binx,biny,mean);
569  }
570  }
571  }
572 
573  return;
574 }
void setBinContent(int binx, double content)
set content of bin (1-D)
int getNbinsY(void) const
get # of bins in Y-axis
void Fill(long long x)
double getBinContent(int binx) const
get content of bin (1-D)
int getNbinsX(void) const
get # of bins in X-axis
void CSCOfflineMonitor::histoEfficiency ( TH1F *  readHisto,
MonitorElement writeHisto 
)
private

Definition at line 1750 of file CSCOfflineMonitor.cc.

References getEfficiency(), i, SiStripMonitorClusterAlca_cfi::Nbins, MonitorElement::setBinContent(), and MonitorElement::setBinError().

Referenced by finalize().

1750  {
1751  std::vector<float> eff(2);
1752  int Nbins = readHisto->GetSize()-2;//without underflows and overflows
1753  std::vector<float> bins(Nbins);
1754  std::vector<float> Efficiency(Nbins);
1755  std::vector<float> EffError(Nbins);
1756  float Num = 1;
1757  float Den = 1;
1758  for (int i=0;i<20;i++){
1759  Num = readHisto->GetBinContent(i+1);
1760  Den = readHisto->GetBinContent(i+21);
1761  getEfficiency(Num, Den, eff);
1762  Efficiency[i] = eff[0];
1763  EffError[i] = eff[1];
1764  writeHisto->setBinContent(i+1, Efficiency[i]);
1765  writeHisto->setBinError(i+1, EffError[i]);
1766  }
1767 }
int i
Definition: DBlmapReader.cc:9
void setBinContent(int binx, double content)
set content of bin (1-D)
void setBinError(int binx, double error)
set uncertainty on content of bin (1-D)
void getEfficiency(float bin, float Norm, std::vector< float > &eff)
double CSCOfflineMonitor::lineParametrization ( double  z1Position,
double  z2Position,
double  z1Direction 
)
inlineprivate

Definition at line 130 of file CSCOfflineMonitor.h.

Referenced by doEfficiencies().

130  {
131  double parameterLine = (z2Position-z1Position)/z1Direction;
132  return parameterLine;
133  }
void CSCOfflineMonitor::normalize ( MonitorElement me)
private

Definition at line 576 of file CSCOfflineMonitor.cc.

References python.tagInventory::entries, MonitorElement::getTH2F(), and h.

Referenced by finalize().

576  {
577 
578  TH2F* h = me->getTH2F();
579  if (! h)
580  return;
581  TH1D* hproj = h->ProjectionX("hproj");
582 
583  for (int binx = 0; binx < h->GetNbinsX()+1 ; binx++){
584  Double_t entries = hproj->GetBinContent(binx);
585  for (Int_t biny=1;biny <= h->GetNbinsY();biny++) {
586  Double_t cxy = h->GetBinContent(binx,biny);
587  if (cxy > 0 && entries>0) h->SetBinContent(binx,biny,cxy/entries);
588  }
589  }
590 
591 
592  return;
593 
594 }
The Signals That Services Can Subscribe To This is based on ActivityRegistry h
Helper function to determine trigger accepts.
Definition: Activities.doc:4
TH2F * getTH2F(void) const
int CSCOfflineMonitor::typeIndex ( CSCDetId  id,
int  flag = 1 
)
private

Definition at line 1870 of file CSCOfflineMonitor.cc.

References Reference_intrackfit_cff::endcap, cmsHarvester::index, relativeConstraints::ring, and relativeConstraints::station.

Referenced by doBXMonitor(), doOccupancies(), doPedestalNoise(), doRecHits(), doResolution(), doSegments(), doStripDigis(), and doWireDigis().

1870  {
1871 
1872  if (flag == 1){
1873  // linearlized index bases on endcap, station, and ring
1874  int index = 0;
1875  if (id.station() == 1) index = id.ring();
1876  else index = id.station()*2 + id.ring();
1877  if (id.endcap() == 1) index = index + 10;
1878  if (id.endcap() == 2) index = 11 - index;
1879  return index;
1880  }
1881 
1882  else if (flag == 2){
1883  int index = 0;
1884  if (id.station() == 1 && id.ring() != 4) index = id.ring()+1;
1885  if (id.station() == 1 && id.ring() == 4) index = 1;
1886  if (id.station() != 1) index = id.station()*2 + id.ring();
1887  if (id.endcap() == 1) index = index + 10;
1888  if (id.endcap() == 2) index = 11 - index;
1889  return index;
1890  }
1891 
1892  else return 0;
1893 
1894 }
bool CSCOfflineMonitor::withinSensitiveRegion ( LocalPoint  localPos,
const std::array< const float, 4 > &  layerBounds,
int  station,
int  ring,
float  shiftFromEdge,
float  shiftFromDeadZone 
)
private

Definition at line 1769 of file CSCOfflineMonitor.cc.

References funct::abs(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by doEfficiencies().

1770  {
1771 //---- check if it is in a good local region (sensitive area - geometrical and HV boundaries excluded)
1772  bool pass = false;
1773 
1774  float y_center = 0.;
1775  double yUp = layerBounds[3] + y_center;
1776  double yDown = - layerBounds[3] + y_center;
1777  double xBound1Shifted = layerBounds[0] - shiftFromEdge;//
1778  double xBound2Shifted = layerBounds[1] - shiftFromEdge;//
1779  double lineSlope = (yUp - yDown)/(xBound2Shifted-xBound1Shifted);
1780  double lineConst = yUp - lineSlope*xBound2Shifted;
1781  double yBorder = lineSlope*abs(localPos.x()) + lineConst;
1782 
1783  //bool withinChamberOnly = false;// false = "good region"; true - boundaries only
1784  std::vector <float> deadZoneCenter(6);
1785  float cutZone = shiftFromDeadZone;//cm
1786  //---- hardcoded... not good
1787  if(station>1 && station<5){
1788  if(2==ring){
1789  deadZoneCenter[0]= -162.48 ;
1790  deadZoneCenter[1] = -81.8744;
1791  deadZoneCenter[2] = -21.18165;
1792  deadZoneCenter[3] = 39.51105;
1793  deadZoneCenter[4] = 100.2939;
1794  deadZoneCenter[5] = 160.58;
1795 
1796  if(localPos.y() >yBorder &&
1797  ((localPos.y()> deadZoneCenter[0] + cutZone && localPos.y()< deadZoneCenter[1] - cutZone) ||
1798  (localPos.y()> deadZoneCenter[1] + cutZone && localPos.y()< deadZoneCenter[2] - cutZone) ||
1799  (localPos.y()> deadZoneCenter[2] + cutZone && localPos.y()< deadZoneCenter[3] - cutZone) ||
1800  (localPos.y()> deadZoneCenter[3] + cutZone && localPos.y()< deadZoneCenter[4] - cutZone) ||
1801  (localPos.y()> deadZoneCenter[4] + cutZone && localPos.y()< deadZoneCenter[5] - cutZone))){
1802  pass = true;
1803  }
1804  }
1805  else if(1==ring){
1806  if(2==station){
1807  deadZoneCenter[0]= -95.80 ;
1808  deadZoneCenter[1] = -27.47;
1809  deadZoneCenter[2] = 33.67;
1810  deadZoneCenter[3] = 90.85;
1811  }
1812  else if(3==station){
1813  deadZoneCenter[0]= -89.305 ;
1814  deadZoneCenter[1] = -39.705;
1815  deadZoneCenter[2] = 20.195;
1816  deadZoneCenter[3] = 77.395;
1817  }
1818  else if(4==station){
1819  deadZoneCenter[0]= -75.645;
1820  deadZoneCenter[1] = -26.055;
1821  deadZoneCenter[2] = 23.855;
1822  deadZoneCenter[3] = 70.575;
1823  }
1824  if(localPos.y() >yBorder &&
1825  ((localPos.y()> deadZoneCenter[0] + cutZone && localPos.y()< deadZoneCenter[1] - cutZone) ||
1826  (localPos.y()> deadZoneCenter[1] + cutZone && localPos.y()< deadZoneCenter[2] - cutZone) ||
1827  (localPos.y()> deadZoneCenter[2] + cutZone && localPos.y()< deadZoneCenter[3] - cutZone))){
1828  pass = true;
1829  }
1830  }
1831  }
1832  else if(1==station){
1833  if(3==ring){
1834  deadZoneCenter[0]= -83.155 ;
1835  deadZoneCenter[1] = -22.7401;
1836  deadZoneCenter[2] = 27.86665;
1837  deadZoneCenter[3] = 81.005;
1838  if(localPos.y() > yBorder &&
1839  ((localPos.y()> deadZoneCenter[0] + cutZone && localPos.y()< deadZoneCenter[1] - cutZone) ||
1840  (localPos.y()> deadZoneCenter[1] + cutZone && localPos.y()< deadZoneCenter[2] - cutZone) ||
1841  (localPos.y()> deadZoneCenter[2] + cutZone && localPos.y()< deadZoneCenter[3] - cutZone))){
1842  pass = true;
1843  }
1844  }
1845  else if(2==ring){
1846  deadZoneCenter[0]= -86.285 ;
1847  deadZoneCenter[1] = -32.88305;
1848  deadZoneCenter[2] = 32.867423;
1849  deadZoneCenter[3] = 88.205;
1850  if(localPos.y() > (yBorder) &&
1851  ((localPos.y()> deadZoneCenter[0] + cutZone && localPos.y()< deadZoneCenter[1] - cutZone) ||
1852  (localPos.y()> deadZoneCenter[1] + cutZone && localPos.y()< deadZoneCenter[2] - cutZone) ||
1853  (localPos.y()> deadZoneCenter[2] + cutZone && localPos.y()< deadZoneCenter[3] - cutZone))){
1854  pass = true;
1855  }
1856  }
1857  else{
1858  deadZoneCenter[0]= -81.0;
1859  deadZoneCenter[1] = 81.0;
1860  if(localPos.y() > (yBorder) &&
1861  (localPos.y()> deadZoneCenter[0] + cutZone && localPos.y()< deadZoneCenter[1] - cutZone )){
1862  pass = true;
1863  }
1864  }
1865  }
1866  return pass;
1867 }
T y() const
Definition: PV3DBase.h:63
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
T x() const
Definition: PV3DBase.h:62

Member Data Documentation

edm::EDGetTokenT<CSCALCTDigiCollection> CSCOfflineMonitor::al_token
private

Definition at line 96 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

edm::EDGetTokenT<CSCCLCTDigiCollection> CSCOfflineMonitor::cl_token
private

Definition at line 97 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

DQMStore* CSCOfflineMonitor::dbe
private

Definition at line 146 of file CSCOfflineMonitor.h.

Referenced by beginRun(), bookTheHists(), endJob(), and finalize().

bool CSCOfflineMonitor::finalizedHistograms_
private

Definition at line 89 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), CSCOfflineMonitor(), endJob(), and endRun().

MonitorElement* CSCOfflineMonitor::hALCTgetBX
private

Definition at line 217 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doBXMonitor().

MonitorElement* CSCOfflineMonitor::hALCTgetBX2Denominator
private

Definition at line 221 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTgetBX2DMeans
private

Definition at line 220 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTgetBX2DNumerator
private

Definition at line 222 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTgetBXChamberMeans
private

Definition at line 219 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTgetBXSerial
private

Definition at line 218 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTMatch
private

Definition at line 224 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doBXMonitor().

MonitorElement* CSCOfflineMonitor::hALCTMatch2Denominator
private

Definition at line 228 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTMatch2DMeans
private

Definition at line 227 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTMatch2DNumerator
private

Definition at line 229 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTMatchChamberMeans
private

Definition at line 226 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hALCTMatchSerial
private

Definition at line 225 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hCLCTL1A
private

Definition at line 231 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doBXMonitor().

MonitorElement* CSCOfflineMonitor::hCLCTL1A2Denominator
private

Definition at line 235 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hCLCTL1A2DMeans
private

Definition at line 234 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hCLCTL1A2DNumerator
private

Definition at line 236 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hCLCTL1AChamberMeans
private

Definition at line 233 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hCLCTL1ASerial
private

Definition at line 232 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doBXMonitor(), and finalize().

MonitorElement* CSCOfflineMonitor::hCSCOccupancy
private

Definition at line 197 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hEffDenominator
private

Definition at line 213 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

MonitorElement* CSCOfflineMonitor::hORecHits
private

Definition at line 191 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hORecHitsSerial
private

Definition at line 195 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOSegments
private

Definition at line 192 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOSegmentsSerial
private

Definition at line 196 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOStrips
private

Definition at line 189 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOStripsAndWiresAndCLCT
private

Definition at line 190 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doOccupancies(), and finalize().

MonitorElement* CSCOfflineMonitor::hOStripSerial
private

Definition at line 194 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOWires
private

Definition at line 187 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hOWiresAndCLCT
private

Definition at line 188 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doOccupancies(), and finalize().

MonitorElement* CSCOfflineMonitor::hOWireSerial
private

Definition at line 193 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doOccupancies().

MonitorElement* CSCOfflineMonitor::hRHEff
private

Definition at line 203 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hRHEff2
private

Definition at line 209 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHGlobal
private

Definition at line 160 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

MonitorElement* CSCOfflineMonitor::hRHnrechits
private

Definition at line 159 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHRatioQ
private

Definition at line 164 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

MonitorElement* CSCOfflineMonitor::hRHSTE
private

Definition at line 201 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

MonitorElement* CSCOfflineMonitor::hRHSTE2
private

Definition at line 205 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHsterr
private

Definition at line 166 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHstpos
private

Definition at line 165 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHSumQ
private

Definition at line 161 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHTiming
private

Definition at line 162 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hRHTimingAnode
private

Definition at line 163 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doRecHits().

std::vector<MonitorElement*> CSCOfflineMonitor::hSChiSq
private

Definition at line 173 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSChiSqAll
private

Definition at line 172 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

std::vector<MonitorElement*> CSCOfflineMonitor::hSChiSqProb
private

Definition at line 175 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSChiSqProbAll
private

Definition at line 174 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSEff
private

Definition at line 202 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hSEff2
private

Definition at line 208 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hSensitiveAreaEvt
private

Definition at line 214 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doEfficiencies().

MonitorElement* CSCOfflineMonitor::hSGlobalPhi
private

Definition at line 177 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSGlobalTheta
private

Definition at line 176 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

std::vector<MonitorElement*> CSCOfflineMonitor::hSnhits
private

Definition at line 171 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSnhitsAll
private

Definition at line 170 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSnSegments
private

Definition at line 169 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

std::vector<MonitorElement*> CSCOfflineMonitor::hSResid
private

Definition at line 184 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doResolution().

MonitorElement* CSCOfflineMonitor::hSSTE
private

Definition at line 200 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

MonitorElement* CSCOfflineMonitor::hSSTE2
private

Definition at line 204 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

MonitorElement* CSCOfflineMonitor::hSTimeCathode
private

Definition at line 178 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSTimeCombined
private

Definition at line 179 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSTimeVsTOF
private

Definition at line 181 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hSTimeVsZ
private

Definition at line 180 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doSegments().

MonitorElement* CSCOfflineMonitor::hStripEff2
private

Definition at line 210 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hStripNFired
private

Definition at line 154 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doStripDigis().

std::vector<MonitorElement*> CSCOfflineMonitor::hStripNumber
private

Definition at line 155 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doStripDigis().

std::vector<MonitorElement*> CSCOfflineMonitor::hStripPed
private

Definition at line 156 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doPedestalNoise().

MonitorElement* CSCOfflineMonitor::hStripReadoutEff2
private

Definition at line 212 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hStripSTE2
private

Definition at line 206 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

MonitorElement* CSCOfflineMonitor::hWireEff2
private

Definition at line 211 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and finalize().

MonitorElement* CSCOfflineMonitor::hWirenGroupsTotal
private

Definition at line 149 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doWireDigis().

std::vector<MonitorElement*> CSCOfflineMonitor::hWireNumber
private

Definition at line 151 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doWireDigis().

MonitorElement* CSCOfflineMonitor::hWireSTE2
private

Definition at line 207 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), doEfficiencies(), and finalize().

std::vector<MonitorElement*> CSCOfflineMonitor::hWireTBin
private

Definition at line 150 of file CSCOfflineMonitor.h.

Referenced by bookTheHists(), and doWireDigis().

edm::ParameterSet CSCOfflineMonitor::param
private

Definition at line 91 of file CSCOfflineMonitor.h.

Referenced by CSCOfflineMonitor(), and endJob().

edm::EDGetTokenT<FEDRawDataCollection> CSCOfflineMonitor::rd_token
private

Definition at line 93 of file CSCOfflineMonitor.h.

Referenced by CSCOfflineMonitor(), and doBXMonitor().

edm::EDGetTokenT<CSCRecHit2DCollection> CSCOfflineMonitor::rh_token
private

Definition at line 98 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

edm::EDGetTokenT<CSCStripDigiCollection> CSCOfflineMonitor::sd_token
private

Definition at line 95 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

edm::EDGetTokenT<CSCSegmentCollection> CSCOfflineMonitor::se_token
private

Definition at line 99 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

edm::EDGetTokenT<CSCWireDigiCollection> CSCOfflineMonitor::wd_token
private

Definition at line 94 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().