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CSCOfflineMonitor Class Reference

#include <CSCOfflineMonitor.h>

Inheritance diagram for CSCOfflineMonitor:
DQMEDAnalyzer edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >

Public Types

enum  AxisType { X = 1, Y = 2, Z = 3 }
 
enum  LabelType { SMALL, EXTENDED }
 
- Public Types inherited from DQMEDAnalyzer
typedef dqm::reco::DQMStore DQMStore
 
typedef dqm::reco::MonitorElement MonitorElement
 
- Public Types inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
using CacheTypes = CacheContexts< T... >
 
using GlobalCache = typename CacheTypes::GlobalCache
 
using HasAbility = AbilityChecker< T... >
 
using InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache
 
using LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache
 
using LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >
 
using LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache
 
using RunCache = typename CacheTypes::RunCache
 
using RunContext = RunContextT< RunCache, GlobalCache >
 
using RunSummaryCache = typename CacheTypes::RunSummaryCache
 

Public Member Functions

 CSCOfflineMonitor (const edm::ParameterSet &pset)
 
 ~CSCOfflineMonitor () override
 
- Public Member Functions inherited from DQMEDAnalyzer
void accumulate (edm::Event const &event, edm::EventSetup const &setup) final
 
void beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final
 
void beginRun (edm::Run const &run, edm::EventSetup const &setup) final
 
void beginStream (edm::StreamID id) final
 
virtual void dqmBeginRun (edm::Run const &, edm::EventSetup const &)
 
 DQMEDAnalyzer ()
 
void endLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final
 
void endRun (edm::Run const &run, edm::EventSetup const &setup) final
 
virtual bool getCanSaveByLumi ()
 
- Public Member Functions inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
 EDProducer ()=default
 
 EDProducer (const EDProducer &)=delete
 
bool hasAbilityToProduceInBeginLumis () const final
 
bool hasAbilityToProduceInBeginProcessBlocks () const final
 
bool hasAbilityToProduceInBeginRuns () const final
 
bool hasAbilityToProduceInEndLumis () const final
 
bool hasAbilityToProduceInEndProcessBlocks () const final
 
bool hasAbilityToProduceInEndRuns () const final
 
const EDProduceroperator= (const EDProducer &)=delete
 

Protected Member Functions

void analyze (const edm::Event &event, const edm::EventSetup &eventSetup) override
 
void bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
 
- Protected Member Functions inherited from DQMEDAnalyzer
uint64_t meId () const
 

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, edm::ESHandle< CSCGeometry > cscGeom)
 
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)
 
float getSignal (const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
 
double lineParametrization (double z1Position, double z2Position, double z1Direction)
 
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< CSCALCTDigiCollectional_token
 
edm::EDGetTokenT< CSCCLCTDigiCollectioncl_token
 
const edm::ESGetToken< CSCGeometry, MuonGeometryRecordcscGeomToken_
 
MonitorElementhALCTgetBX
 
MonitorElementhALCTgetBX2Denominator
 
MonitorElementhALCTgetBX2DNumerator
 
MonitorElementhALCTgetBXSerial
 
MonitorElementhALCTMatch
 
MonitorElementhALCTMatch2Denominator
 
MonitorElementhALCTMatch2DNumerator
 
MonitorElementhALCTMatchSerial
 
MonitorElementhCLCTL1A
 
MonitorElementhCLCTL1A2Denominator
 
MonitorElementhCLCTL1A2DNumerator
 
MonitorElementhCLCTL1ASerial
 
const edm::ESGetToken< CSCCrateMap, CSCCrateMapRcdhcrateToken_
 
MonitorElementhCSCOccupancy
 
MonitorElementhEffDenominator
 
MonitorElementhORecHits
 
MonitorElementhORecHitsSerial
 
MonitorElementhOSegments
 
MonitorElementhOSegmentsSerial
 
MonitorElementhOStrips
 
MonitorElementhOStripsAndWiresAndCLCT
 
MonitorElementhOStripSerial
 
MonitorElementhOWires
 
MonitorElementhOWiresAndCLCT
 
MonitorElementhOWireSerial
 
MonitorElementhRHden
 
std::vector< MonitorElement * > hRHGlobal
 
MonitorElementhRHnrechits
 
MonitorElementhRHnrechitsHi
 
MonitorElementhRHnum
 
std::vector< MonitorElement * > hRHRatioQ
 
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
 
MonitorElementhSden
 
MonitorElementhSensitiveAreaEvt
 
MonitorElementhSGlobalPhi
 
MonitorElementhSGlobalTheta
 
std::vector< MonitorElement * > hSnhits
 
MonitorElementhSnhitsAll
 
MonitorElementhSnSegments
 
MonitorElementhSnum
 
std::vector< MonitorElement * > hSResid
 
MonitorElementhSSTE2
 
MonitorElementhSTimeAnode
 
std::vector< MonitorElement * > hSTimeAnodeByChamberType
 
MonitorElementhSTimeAnodeSerial
 
MonitorElementhSTimeCathode
 
std::vector< MonitorElement * > hSTimeCathodeByChamberType
 
MonitorElementhSTimeCathodeSerial
 
MonitorElementhSTimeCombined
 
std::vector< MonitorElement * > hSTimeCombinedByChamberType
 
MonitorElementhSTimeCombinedSerial
 
MonitorElementhSTimeDiff
 
std::vector< MonitorElement * > hSTimeDiffByChamberType
 
MonitorElementhSTimeDiffSerial
 
MonitorElementhSTimeVsTOF
 
MonitorElementhSTimeVsZ
 
MonitorElementhStripNFired
 
MonitorElementhStripNFiredHi
 
std::vector< MonitorElement * > hStripNumber
 
std::vector< MonitorElement * > hStripPed
 
MonitorElementhStripSTE2
 
MonitorElementhWirenGroupsTotal
 
MonitorElementhWirenGroupsTotalHi
 
std::vector< MonitorElement * > hWireNumber
 
MonitorElementhWireSTE2
 
std::vector< MonitorElement * > hWireTBin
 
edm::ParameterSet param
 
edm::EDGetTokenT< FEDRawDataCollectionrd_token
 
edm::EDGetTokenT< CSCRecHit2DCollectionrh_token
 
edm::EDGetTokenT< CSCStripDigiCollectionsd_token
 
edm::EDGetTokenT< CSCSegmentCollectionse_token
 
edm::EDGetTokenT< CSCWireDigiCollectionwd_token
 

Additional Inherited Members

- Static Public Member Functions inherited from DQMEDAnalyzer
static void globalEndJob (DQMEDAnalyzerGlobalCache const *)
 
static void globalEndLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &setup, LuminosityBlockContext const *context)
 
static void globalEndRunProduce (edm::Run &run, edm::EventSetup const &setup, RunContext const *context)
 
static std::unique_ptr< DQMEDAnalyzerGlobalCacheinitializeGlobalCache (edm::ParameterSet const &)
 
- Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMTokenlumiToken_
 
edm::EDPutTokenT< DQMTokenrunToken_
 
unsigned int streamId_
 

Detailed Description

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

Andrew Kubik, Northwestern University, Oct 2008

Definition at line 71 of file CSCOfflineMonitor.h.

Member Enumeration Documentation

◆ AxisType

Enumerator

Definition at line 77 of file CSCOfflineMonitor.h.

◆ LabelType

Enumerator
SMALL 
EXTENDED 

Definition at line 76 of file CSCOfflineMonitor.h.

Constructor & Destructor Documentation

◆ CSCOfflineMonitor()

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

Definition at line 13 of file CSCOfflineMonitor.cc.

References al_token, cl_token, muonDTDigis_cfi::pset, rd_token, rh_token, sd_token, se_token, and wd_token.

14  : cscGeomToken_(esConsumes<CSCGeometry, MuonGeometryRecord>()),
15  hcrateToken_(esConsumes<CSCCrateMap, CSCCrateMapRcd>()) {
16  rd_token = consumes<FEDRawDataCollection>(pset.getParameter<edm::InputTag>("FEDRawDataCollectionTag"));
17  sd_token = consumes<CSCStripDigiCollection>(pset.getParameter<edm::InputTag>("stripDigiTag"));
18  wd_token = consumes<CSCWireDigiCollection>(pset.getParameter<edm::InputTag>("wireDigiTag"));
19  al_token = consumes<CSCALCTDigiCollection>(pset.getParameter<edm::InputTag>("alctDigiTag"));
20  cl_token = consumes<CSCCLCTDigiCollection>(pset.getParameter<edm::InputTag>("clctDigiTag"));
21  rh_token = consumes<CSCRecHit2DCollection>(pset.getParameter<edm::InputTag>("cscRecHitTag"));
22  se_token = consumes<CSCSegmentCollection>(pset.getParameter<edm::InputTag>("cscSegTag"));
23 }
edm::EDGetTokenT< CSCALCTDigiCollection > al_token
const edm::ESGetToken< CSCCrateMap, CSCCrateMapRcd > hcrateToken_
edm::EDGetTokenT< CSCWireDigiCollection > wd_token
const edm::ESGetToken< CSCGeometry, MuonGeometryRecord > cscGeomToken_
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

◆ ~CSCOfflineMonitor()

CSCOfflineMonitor::~CSCOfflineMonitor ( )
inlineoverride

Definition at line 74 of file CSCOfflineMonitor.h.

74 {};

Member Function Documentation

◆ analyze()

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

Reimplemented from DQMEDAnalyzer.

Definition at line 826 of file CSCOfflineMonitor.cc.

References al_token, cl_token, cscGeomToken_, dtChamberEfficiency_cfi::cscSegments, doBXMonitor(), doEfficiencies(), doOccupancies(), doPedestalNoise(), doRecHits(), doResolution(), doSegments(), doStripDigis(), doWireDigis(), options_cfi::eventSetup, FastTrackerRecHitMaskProducer_cfi::recHits, rh_token, sd_token, se_token, DigiDM_cff::strips, wd_token, and DigiDM_cff::wires.

826  {
831  event.getByToken(sd_token, strips);
832  event.getByToken(wd_token, wires);
833  event.getByToken(al_token, alcts);
834  event.getByToken(cl_token, clcts);
835 
836  // Get the CSC Geometry :
838 
839  cscGeom = eventSetup.getHandle(cscGeomToken_);
840 
841  // Get the RecHits collection :
843  event.getByToken(rh_token, recHits);
844 
845  // get CSC segment collection
847  event.getByToken(se_token, cscSegments);
848 
852  doRecHits(recHits, strips, cscGeom);
853  doSegments(cscSegments, cscGeom);
854  doResolution(cscSegments, cscGeom);
855  doPedestalNoise(strips, cscGeom);
857  doBXMonitor(alcts, clcts, event, eventSetup);
858 }
edm::EDGetTokenT< CSCALCTDigiCollection > al_token
void doResolution(edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
edm::EDGetTokenT< CSCWireDigiCollection > wd_token
const edm::ESGetToken< CSCGeometry, MuonGeometryRecord > cscGeomToken_
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)
void doBXMonitor(edm::Handle< CSCALCTDigiCollection > alcts, edm::Handle< CSCCLCTDigiCollection > clcts, const edm::Event &event, const edm::EventSetup &eventSetup)
void doStripDigis(edm::Handle< CSCStripDigiCollection > strips)
void doPedestalNoise(edm::Handle< CSCStripDigiCollection > strips, edm::ESHandle< CSCGeometry > cscGeom)
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32
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)
Definition: event.py:1
void doRecHits(edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCStripDigiCollection > strips, edm::ESHandle< CSCGeometry > cscGeom)

◆ applyCSClabels()

void CSCOfflineMonitor::applyCSClabels ( MonitorElement meHisto,
LabelType  t,
AxisType  a 
)
private

Definition at line 2149 of file CSCOfflineMonitor.cc.

References a, EXTENDED, hlt_dqm_clientPB-live_cfg::me, SMALL, and submitPVValidationJobs::t.

Referenced by bookHistograms().

2149  {
2150  if (me != nullptr) {
2151  me->setAxisTitle("Chamber #");
2152  if (t == EXTENDED) {
2153  me->setBinLabel(1, "ME -4/2", a);
2154  me->setBinLabel(2, "ME -4/1", a);
2155  me->setBinLabel(3, "ME -3/2", a);
2156  me->setBinLabel(4, "ME -3/1", a);
2157  me->setBinLabel(5, "ME -2/2", a);
2158  me->setBinLabel(6, "ME -2/1", a);
2159  me->setBinLabel(7, "ME -1/3", a);
2160  me->setBinLabel(8, "ME -1/2", a);
2161  me->setBinLabel(9, "ME -1/1b", a);
2162  me->setBinLabel(10, "ME -1/1a", a);
2163  me->setBinLabel(11, "ME +1/1a", a);
2164  me->setBinLabel(12, "ME +1/1b", a);
2165  me->setBinLabel(13, "ME +1/2", a);
2166  me->setBinLabel(14, "ME +1/3", a);
2167  me->setBinLabel(15, "ME +2/1", a);
2168  me->setBinLabel(16, "ME +2/2", a);
2169  me->setBinLabel(17, "ME +3/1", a);
2170  me->setBinLabel(18, "ME +3/2", a);
2171  me->setBinLabel(19, "ME +4/1", a);
2172  me->setBinLabel(20, "ME +4/2", a);
2173  } else if (t == SMALL) {
2174  me->setBinLabel(1, "ME -4/1", a);
2175  me->setBinLabel(2, "ME -3/2", a);
2176  me->setBinLabel(3, "ME -3/1", a);
2177  me->setBinLabel(4, "ME -2/2", a);
2178  me->setBinLabel(5, "ME -2/1", a);
2179  me->setBinLabel(6, "ME -1/3", a);
2180  me->setBinLabel(7, "ME -1/2", a);
2181  me->setBinLabel(8, "ME -1/1b", a);
2182  me->setBinLabel(9, "ME -1/1a", a);
2183  me->setBinLabel(10, "ME +1/1a", a);
2184  me->setBinLabel(11, "ME +1/1b", a);
2185  me->setBinLabel(12, "ME +1/2", a);
2186  me->setBinLabel(13, "ME +1/3", a);
2187  me->setBinLabel(14, "ME +2/1", a);
2188  me->setBinLabel(15, "ME +2/2", a);
2189  me->setBinLabel(16, "ME +3/1", a);
2190  me->setBinLabel(17, "ME +3/2", a);
2191  me->setBinLabel(18, "ME +4/1", a);
2192  }
2193  }
2194 }
double a
Definition: hdecay.h:119

◆ bookHistograms()

void CSCOfflineMonitor::bookHistograms ( DQMStore::IBooker ibooker,
edm::Run const &  iRun,
edm::EventSetup const &   
)
overrideprotectedvirtual

Implements DQMEDAnalyzer.

Definition at line 25 of file CSCOfflineMonitor.cc.

References applyCSClabels(), dqm::implementation::IBooker::book1D(), dqm::implementation::IBooker::book2D(), dqm::implementation::NavigatorBase::cd(), EXTENDED, hALCTgetBX, hALCTgetBX2Denominator, hALCTgetBX2DNumerator, hALCTgetBXSerial, hALCTMatch, hALCTMatch2Denominator, hALCTMatch2DNumerator, hALCTMatchSerial, hCLCTL1A, hCLCTL1A2Denominator, hCLCTL1A2DNumerator, hCLCTL1ASerial, hCSCOccupancy, hEffDenominator, hORecHits, hORecHitsSerial, hOSegments, hOSegmentsSerial, hOStrips, hOStripsAndWiresAndCLCT, hOStripSerial, hOWires, hOWiresAndCLCT, hOWireSerial, hRHden, hRHGlobal, hRHnrechits, hRHnrechitsHi, hRHnum, hRHRatioQ, hRHSTE2, hRHsterr, hRHstpos, hRHSumQ, hRHTiming, hRHTimingAnode, hSChiSq, hSChiSqAll, hSChiSqProb, hSChiSqProbAll, hSden, hSensitiveAreaEvt, hSGlobalPhi, hSGlobalTheta, hSnhits, hSnhitsAll, hSnSegments, hSnum, hSResid, hSSTE2, hSTimeAnode, hSTimeAnodeByChamberType, hSTimeAnodeSerial, hSTimeCathode, hSTimeCathodeByChamberType, hSTimeCathodeSerial, hSTimeCombined, hSTimeCombinedByChamberType, hSTimeCombinedSerial, hSTimeDiff, hSTimeDiffByChamberType, hSTimeDiffSerial, hSTimeVsTOF, hSTimeVsZ, hStripNFired, hStripNFiredHi, hStripNumber, hStripPed, hStripSTE2, hWirenGroupsTotal, hWirenGroupsTotalHi, hWireNumber, hWireSTE2, hWireTBin, dqm::impl::MonitorElement::setAxisTitle(), dqm::impl::MonitorElement::setBinLabel(), dqm::implementation::NavigatorBase::setCurrentFolder(), X, and Y.

27  {
28  // occupancies
29  ibooker.cd();
30  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/Occupancy");
31 
32  hCSCOccupancy = ibooker.book1D("hCSCOccupancy", "overall CSC occupancy", 13, -0.5, 12.5);
33  hCSCOccupancy->setBinLabel(2, "Total Events");
34  hCSCOccupancy->setBinLabel(4, "# Events with Wires");
35  hCSCOccupancy->setBinLabel(6, "# Events with Strips");
36  hCSCOccupancy->setBinLabel(8, "# Events with Wires&Strips");
37  hCSCOccupancy->setBinLabel(10, "# Events with Rechits");
38  hCSCOccupancy->setBinLabel(12, "# Events with Segments");
39  hOWiresAndCLCT = ibooker.book2D("hOWiresAndCLCT", "Wire and CLCT Digi Occupancy ", 36, 0.5, 36.5, 20, 0.5, 20.5);
40  hOWires = ibooker.book2D("hOWires", "Wire Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
41  hOWireSerial = ibooker.book1D("hOWireSerial", "Wire Occupancy by Chamber Serial", 601, -0.5, 600.5);
42  hOWireSerial->setAxisTitle("Chamber Serial Number");
43  hOStrips = ibooker.book2D("hOStrips", "Strip Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
44  hOStripSerial = ibooker.book1D("hOStripSerial", "Strip Occupancy by Chamber Serial", 601, -0.5, 600.5);
45  hOStripSerial->setAxisTitle("Chamber Serial Number");
47  ibooker.book2D("hOStripsAndWiresAndCLCT", "Strip And Wire And CLCT Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
49  hORecHits = ibooker.book2D("hORecHits", "RecHit Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
50  hORecHitsSerial = ibooker.book1D("hORecHitSerial", "RecHit Occupancy by Chamber Serial", 601, -0.5, 600.5);
51  hORecHitsSerial->setAxisTitle("Chamber Serial Number");
52  hOSegments = ibooker.book2D("hOSegments", "Segment Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
53  hOSegmentsSerial = ibooker.book1D("hOSegmentSerial", "Segment Occupancy by Chamber Serial", 601, -0.5, 600.5);
54  hOSegmentsSerial->setAxisTitle("Chamber Serial Number");
55 
56  // wire digis
57  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/Digis");
58 
59  // For low multiplicities (e.g. low or no pileup)
61  ibooker.book1D("hWirenGroupsTotal", "Fired Wires per Event; # Wiregroups Fired", 250, 0., 250.); // 1 bin is 1
62  // For high multiplcities (e.g. with pileup)
64  ibooker.book1D("hWirenGroupsTotalHi", "Fired Wires per Event; # Wiregroups Fired", 250, 0., 1000.); // i bin is 4
65 
66  hWireTBin.push_back(ibooker.book1D("hWireTBin_m42", "Wire TBin Fired (ME -4/2); Time Bin (25ns)", 17, -0.5, 16.5));
67  hWireTBin.push_back(ibooker.book1D("hWireTBin_m41", "Wire TBin Fired (ME -4/1); Time Bin (25ns)", 17, -0.5, 16.5));
68  hWireTBin.push_back(ibooker.book1D("hWireTBin_m32", "Wire TBin Fired (ME -3/2); Time Bin (25ns)", 17, -0.5, 16.5));
69  hWireTBin.push_back(ibooker.book1D("hWireTBin_m31", "Wire TBin Fired (ME -3/1); Time Bin (25ns)", 17, -0.5, 16.5));
70  hWireTBin.push_back(ibooker.book1D("hWireTBin_m22", "Wire TBin Fired (ME -2/2); Time Bin (25ns)", 17, -0.5, 16.5));
71  hWireTBin.push_back(ibooker.book1D("hWireTBin_m21", "Wire TBin Fired (ME -2/1); Time Bin (25ns)", 17, -0.5, 16.5));
72  hWireTBin.push_back(ibooker.book1D("hWireTBin_m11a", "Wire TBin Fired (ME -1/1a); Time Bin (25ns)", 17, -0.5, 16.5));
73  hWireTBin.push_back(ibooker.book1D("hWireTBin_m13", "Wire TBin Fired (ME -1/3); Time Bin (25ns)", 17, -0.5, 16.5));
74  hWireTBin.push_back(ibooker.book1D("hWireTBin_m12", "Wire TBin Fired (ME -1/2); Time Bin (25ns)", 17, -0.5, 16.5));
75  hWireTBin.push_back(ibooker.book1D("hWireTBin_m11b", "Wire TBin Fired (ME -1/1b); Time Bin (25ns)", 17, -0.5, 16.5));
76  hWireTBin.push_back(ibooker.book1D("hWireTBin_p11b", "Wire TBin Fired (ME +1/1b); Time Bin (25ns)", 17, -0.5, 16.5));
77  hWireTBin.push_back(ibooker.book1D("hWireTBin_p12", "Wire TBin Fired (ME +1/2); Time Bin (25ns)", 17, -0.5, 16.5));
78  hWireTBin.push_back(ibooker.book1D("hWireTBin_p13", "Wire TBin Fired (ME +1/3); Time Bin (25ns)", 17, -0.5, 16.5));
79  hWireTBin.push_back(ibooker.book1D("hWireTBin_p11a", "Wire TBin Fired (ME +1/1a); Time Bin (25ns)", 17, -0.5, 16.5));
80  hWireTBin.push_back(ibooker.book1D("hWireTBin_p21", "Wire TBin Fired (ME +2/1); Time Bin (25ns)", 17, -0.5, 16.5));
81  hWireTBin.push_back(ibooker.book1D("hWireTBin_p22", "Wire TBin Fired (ME +2/2); Time Bin (25ns)", 17, -0.5, 16.5));
82  hWireTBin.push_back(ibooker.book1D("hWireTBin_p31", "Wire TBin Fired (ME +3/1); Time Bin (25ns)", 17, -0.5, 16.5));
83  hWireTBin.push_back(ibooker.book1D("hWireTBin_p32", "Wire TBin Fired (ME +3/2); Time Bin (25ns)", 17, -0.5, 16.5));
84  hWireTBin.push_back(ibooker.book1D("hWireTBin_p41", "Wire TBin Fired (ME +4/1); Time Bin (25ns)", 17, -0.5, 16.5));
85  hWireTBin.push_back(ibooker.book1D("hWireTBin_p42", "Wire TBin Fired (ME +4/2); Time Bin (25ns)", 17, -0.5, 16.5));
86  hWireNumber.push_back(
87  ibooker.book1D("hWireNumber_m42", "Wiregroup Number Fired (ME -4/2); Wiregroup #", 113, -0.5, 112.5));
88  hWireNumber.push_back(
89  ibooker.book1D("hWireNumber_m41", "Wiregroup Number Fired (ME -4/1); Wiregroup #", 113, -0.5, 112.5));
90  hWireNumber.push_back(
91  ibooker.book1D("hWireNumber_m32", "Wiregroup Number Fired (ME -3/2); Wiregroup #", 113, -0.5, 112.5));
92  hWireNumber.push_back(
93  ibooker.book1D("hWireNumber_m31", "Wiregroup Number Fired (ME -3/1); Wiregroup #", 113, -0.5, 112.5));
94  hWireNumber.push_back(
95  ibooker.book1D("hWireNumber_m22", "Wiregroup Number Fired (ME -2/2); Wiregroup #", 113, -0.5, 112.5));
96  hWireNumber.push_back(
97  ibooker.book1D("hWireNumber_m21", "Wiregroup Number Fired (ME -2/1); Wiregroup #", 113, -0.5, 112.5));
98  hWireNumber.push_back(
99  ibooker.book1D("hWireNumber_m11a", "Wiregroup Number Fired (ME -1/1a); Wiregroup #", 113, -0.5, 112.5));
100  hWireNumber.push_back(
101  ibooker.book1D("hWireNumber_m13", "Wiregroup Number Fired (ME -1/3); Wiregroup #", 113, -0.5, 112.5));
102  hWireNumber.push_back(
103  ibooker.book1D("hWireNumber_m12", "Wiregroup Number Fired (ME -1/2); Wiregroup #", 113, -0.5, 112.5));
104  hWireNumber.push_back(
105  ibooker.book1D("hWireNumber_m11b", "Wiregroup Number Fired (ME -1/1b); Wiregroup #", 113, -0.5, 112.5));
106  hWireNumber.push_back(
107  ibooker.book1D("hWireNumber_p11b", "Wiregroup Number Fired (ME +1/1b); Wiregroup #", 113, -0.5, 112.5));
108  hWireNumber.push_back(
109  ibooker.book1D("hWireNumber_p12", "Wiregroup Number Fired (ME +1/2); Wiregroup #", 113, -0.5, 112.5));
110  hWireNumber.push_back(
111  ibooker.book1D("hWireNumber_p13", "Wiregroup Number Fired (ME +1/3); Wiregroup #", 113, -0.5, 112.5));
112  hWireNumber.push_back(
113  ibooker.book1D("hWireNumber_p11a", "Wiregroup Number Fired (ME +1/1a); Wiregroup #", 113, -0.5, 112.5));
114  hWireNumber.push_back(
115  ibooker.book1D("hWireNumber_p21", "Wiregroup Number Fired (ME +2/1); Wiregroup #", 113, -0.5, 112.5));
116  hWireNumber.push_back(
117  ibooker.book1D("hWireNumber_p22", "Wiregroup Number Fired (ME +2/2); Wiregroup #", 113, -0.5, 112.5));
118  hWireNumber.push_back(
119  ibooker.book1D("hWireNumber_p31", "Wiregroup Number Fired (ME +3/1); Wiregroup #", 113, -0.5, 112.5));
120  hWireNumber.push_back(
121  ibooker.book1D("hWireNumber_p32", "Wiregroup Number Fired (ME +3/2); Wiregroup #", 113, -0.5, 112.5));
122  hWireNumber.push_back(
123  ibooker.book1D("hWireNumber_p41", "Wiregroup Number Fired (ME +4/1); Wiregroup #", 113, -0.5, 112.5));
124  hWireNumber.push_back(
125  ibooker.book1D("hWireNumber_p42", "Wiregroup Number Fired (ME +4/2); Wiregroup #", 113, -0.5, 112.5));
126 
127  // strip digis
128 
129  // For low multiplicities (e.g. low or no pileup)
130  hStripNFired = ibooker.book1D(
131  "hStripNFired", "Fired Strips per Event; # Strips Fired (above 13 ADC)", 400, 0., 400.); // 1 bin is 1
132  // For high multiplcities (e.g. with pileup)
133  hStripNFiredHi = ibooker.book1D(
134  "hStripNFiredHi", "Fired Strips per Event; # Strips Fired (above 13 ADC)", 500, 0., 2000.); // 1 bin is 4
135 
136  hStripNumber.push_back(
137  ibooker.book1D("hStripNumber_m42", "Strip Number Fired (ME -4/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
138  hStripNumber.push_back(
139  ibooker.book1D("hStripNumber_m41", "Strip Number Fired (ME -4/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
140  hStripNumber.push_back(
141  ibooker.book1D("hStripNumber_m32", "Strip Number Fired (ME -3/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
142  hStripNumber.push_back(
143  ibooker.book1D("hStripNumber_m31", "Strip Number Fired (ME -3/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
144  hStripNumber.push_back(
145  ibooker.book1D("hStripNumber_m22", "Strip Number Fired (ME -2/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
146  hStripNumber.push_back(
147  ibooker.book1D("hStripNumber_m21", "Strip Number Fired (ME -2/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
148  hStripNumber.push_back(ibooker.book1D(
149  "hStripNumber_m11a", "Strip Number Fired (ME -1/1a); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
150  hStripNumber.push_back(
151  ibooker.book1D("hStripNumber_m13", "Strip Number Fired (ME -1/3); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
152  hStripNumber.push_back(
153  ibooker.book1D("hStripNumber_m12", "Strip Number Fired (ME -1/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
154  hStripNumber.push_back(ibooker.book1D(
155  "hStripNumber_m11b", "Strip Number Fired (ME -1/1b); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
156  hStripNumber.push_back(ibooker.book1D(
157  "hStripNumber_p11b", "Strip Number Fired (ME +1/1b); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
158  hStripNumber.push_back(
159  ibooker.book1D("hStripNumber_p12", "Strip Number Fired (ME +1/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
160  hStripNumber.push_back(
161  ibooker.book1D("hStripNumber_p13", "Strip Number Fired (ME +1/3); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
162  hStripNumber.push_back(ibooker.book1D(
163  "hStripNumber_p11a", "Strip Number Fired (ME +1/1a); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
164  hStripNumber.push_back(
165  ibooker.book1D("hStripNumber_p21", "Strip Number Fired (ME +2/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
166  hStripNumber.push_back(
167  ibooker.book1D("hStripNumber_p22", "Strip Number Fired (ME +2/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
168  hStripNumber.push_back(
169  ibooker.book1D("hStripNumber_p31", "Strip Number Fired (ME +3/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
170  hStripNumber.push_back(
171  ibooker.book1D("hStripNumber_p32", "Strip Number Fired (ME +3/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
172  hStripNumber.push_back(
173  ibooker.book1D("hStripNumber_p41", "Strip Number Fired (ME +4/1); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
174  hStripNumber.push_back(ibooker.book1D(
175  "hStripNumber_p42", "Stripgroup Number Fired (ME +4/2); Strip # Fired (above 13 ADC)", 81, -0.5, 80.5));
176 
177  // pedestal noise
178  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/PedestalNoise");
179 
180  hStripPed.push_back(
181  ibooker.book1D("hStripPedMEm42", "Pedestal Noise Distribution Chamber ME -4/2; ADC Counts", 50, -25., 25.));
182  hStripPed.push_back(
183  ibooker.book1D("hStripPedMEm41", "Pedestal Noise Distribution Chamber ME -4/1; ADC Counts", 50, -25., 25.));
184  hStripPed.push_back(
185  ibooker.book1D("hStripPedMEm32", "Pedestal Noise Distribution Chamber ME -3/2; ADC Counts", 50, -25., 25.));
186  hStripPed.push_back(
187  ibooker.book1D("hStripPedMEm31", "Pedestal Noise Distribution Chamber ME -3/1; ADC Counts", 50, -25., 25.));
188  hStripPed.push_back(
189  ibooker.book1D("hStripPedMEm22", "Pedestal Noise Distribution Chamber ME -2/2; ADC Counts", 50, -25., 25.));
190  hStripPed.push_back(
191  ibooker.book1D("hStripPedMEm21", "Pedestal Noise Distribution Chamber ME -2/1; ADC Counts", 50, -25., 25.));
192  hStripPed.push_back(
193  ibooker.book1D("hStripPedMEm11a", "Pedestal Noise Distribution Chamber ME -1/1; ADC Counts", 50, -25., 25.));
194  hStripPed.push_back(
195  ibooker.book1D("hStripPedMEm13", "Pedestal Noise Distribution Chamber ME -1/3; ADC Counts", 50, -25., 25.));
196  hStripPed.push_back(
197  ibooker.book1D("hStripPedMEm12", "Pedestal Noise Distribution Chamber ME -1/2; ADC Counts", 50, -25., 25.));
198  hStripPed.push_back(
199  ibooker.book1D("hStripPedMEm11b", "Pedestal Noise Distribution Chamber ME -1/1; ADC Counts", 50, -25., 25.));
200  hStripPed.push_back(
201  ibooker.book1D("hStripPedMEp11b", "Pedestal Noise Distribution Chamber ME +1/1; ADC Counts", 50, -25., 25.));
202  hStripPed.push_back(
203  ibooker.book1D("hStripPedMEp12", "Pedestal Noise Distribution Chamber ME +1/2; ADC Counts", 50, -25., 25.));
204  hStripPed.push_back(
205  ibooker.book1D("hStripPedMEp13", "Pedestal Noise Distribution Chamber ME +1/3; ADC Counts", 50, -25., 25.));
206  hStripPed.push_back(
207  ibooker.book1D("hStripPedMEp11a", "Pedestal Noise Distribution Chamber ME +1/1; ADC Counts", 50, -25., 25.));
208  hStripPed.push_back(
209  ibooker.book1D("hStripPedMEp21", "Pedestal Noise Distribution Chamber ME +2/1; ADC Counts", 50, -25., 25.));
210  hStripPed.push_back(
211  ibooker.book1D("hStripPedMEp22", "Pedestal Noise Distribution Chamber ME +2/2; ADC Counts", 50, -25., 25.));
212  hStripPed.push_back(
213  ibooker.book1D("hStripPedMEp31", "Pedestal Noise Distribution Chamber ME +3/1; ADC Counts", 50, -25., 25.));
214  hStripPed.push_back(
215  ibooker.book1D("hStripPedMEp32", "Pedestal Noise Distribution Chamber ME +3/2; ADC Counts", 50, -25., 25.));
216  hStripPed.push_back(
217  ibooker.book1D("hStripPedMEp41", "Pedestal Noise Distribution Chamber ME +4/1; ADC Counts", 50, -25., 25.));
218  hStripPed.push_back(
219  ibooker.book1D("hStripPedMEp42", "Pedestal Noise Distribution Chamber ME +4/2; ADC Counts", 50, -25., 25.));
220 
221  // rechits
222  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/recHits");
223 
224  // For low multiplicities (e.g. low or no pileup)
225  hRHnrechits = ibooker.book1D("hRHnrechits", "RecHits per Event; # of RecHits", 100, 0., 100.); // 1 bin is 1
226  // For high multiplcities (e.g. with pileup)
227  hRHnrechitsHi = ibooker.book1D("hRHnrechitsHi", "RecHits per Event; # of RecHits", 250, 0., 1000.); // 1 bin is 4
228 
229  hRHGlobal.push_back(ibooker.book2D(
230  "hRHGlobalp1", "recHit global X,Y station +1; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
231  hRHGlobal.push_back(ibooker.book2D(
232  "hRHGlobalp2", "recHit global X,Y station +2; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
233  hRHGlobal.push_back(ibooker.book2D(
234  "hRHGlobalp3", "recHit global X,Y station +3; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
235  hRHGlobal.push_back(ibooker.book2D(
236  "hRHGlobalp4", "recHit global X,Y station +4; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
237  hRHGlobal.push_back(ibooker.book2D(
238  "hRHGlobalm1", "recHit global X,Y station -1; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
239  hRHGlobal.push_back(ibooker.book2D(
240  "hRHGlobalm2", "recHit global X,Y station -2; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
241  hRHGlobal.push_back(ibooker.book2D(
242  "hRHGlobalm3", "recHit global X,Y station -3; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
243  hRHGlobal.push_back(ibooker.book2D(
244  "hRHGlobalm4", "recHit global X,Y station -4; Global X (cm); Global Y (cm)", 100, -800., 800., 100, -800., 800.));
245  hRHSumQ.push_back(ibooker.book1D("hRHSumQm42", "Sum 3x3 recHit Charge (ME -4/2); ADC counts", 100, 0, 2000));
246  hRHSumQ.push_back(ibooker.book1D("hRHSumQm41", "Sum 3x3 recHit Charge (ME -4/1); ADC counts", 100, 0, 2000));
247  hRHSumQ.push_back(ibooker.book1D("hRHSumQm32", "Sum 3x3 recHit Charge (ME -3/2); ADC counts", 100, 0, 2000));
248  hRHSumQ.push_back(ibooker.book1D("hRHSumQm31", "Sum 3x3 recHit Charge (ME -3/1); ADC counts", 100, 0, 2000));
249  hRHSumQ.push_back(ibooker.book1D("hRHSumQm22", "Sum 3x3 recHit Charge (ME -2/2); ADC counts", 100, 0, 2000));
250  hRHSumQ.push_back(ibooker.book1D("hRHSumQm21", "Sum 3x3 recHit Charge (ME -2/1); ADC counts", 100, 0, 2000));
251  hRHSumQ.push_back(ibooker.book1D("hRHSumQm11a", "Sum 3x3 recHit Charge (ME -1/1a); ADC counts", 100, 0, 4000));
252  hRHSumQ.push_back(ibooker.book1D("hRHSumQm13", "Sum 3x3 recHit Charge (ME -1/3); ADC counts", 100, 0, 2000));
253  hRHSumQ.push_back(ibooker.book1D("hRHSumQm12", "Sum 3x3 recHit Charge (ME -1/2); ADC counts", 100, 0, 2000));
254  hRHSumQ.push_back(ibooker.book1D("hRHSumQm11b", "Sum 3x3 recHit Charge (ME -1/1b); ADC counts", 100, 0, 4000));
255  hRHSumQ.push_back(ibooker.book1D("hRHSumQp11b", "Sum 3x3 recHit Charge (ME +1/1b); ADC counts", 100, 0, 4000));
256  hRHSumQ.push_back(ibooker.book1D("hRHSumQp12", "Sum 3x3 recHit Charge (ME +1/2); ADC counts", 100, 0, 2000));
257  hRHSumQ.push_back(ibooker.book1D("hRHSumQp13", "Sum 3x3 recHit Charge (ME +1/3); ADC counts", 100, 0, 2000));
258  hRHSumQ.push_back(ibooker.book1D("hRHSumQp11a", "Sum 3x3 recHit Charge (ME +1/1a); ADC counts", 100, 0, 4000));
259  hRHSumQ.push_back(ibooker.book1D("hRHSumQp21", "Sum 3x3 recHit Charge (ME +2/1); ADC counts", 100, 0, 2000));
260  hRHSumQ.push_back(ibooker.book1D("hRHSumQp22", "Sum 3x3 recHit Charge (ME +2/2); ADC counts", 100, 0, 2000));
261  hRHSumQ.push_back(ibooker.book1D("hRHSumQp31", "Sum 3x3 recHit Charge (ME +3/1); ADC counts", 100, 0, 2000));
262  hRHSumQ.push_back(ibooker.book1D("hRHSumQp32", "Sum 3x3 recHit Charge (ME +3/2); ADC counts", 100, 0, 2000));
263  hRHSumQ.push_back(ibooker.book1D("hRHSumQp41", "Sum 3x3 recHit Charge (ME +4/1); ADC counts", 100, 0, 2000));
264  hRHSumQ.push_back(ibooker.book1D("hRHSumQp42", "Sum 3x3 recHit Charge (ME +4/2); ADC counts", 100, 0, 2000));
265  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm42", "Charge Ratio (Ql+Qr)/Qt (ME -4/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
266  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm41", "Charge Ratio (Ql+Qr)/Qt (ME -4/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
267  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm32", "Charge Ratio (Ql+Qr)/Qt (ME -3/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
268  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm31", "Charge Ratio (Ql+Qr)/Qt (ME -3/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
269  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm22", "Charge Ratio (Ql+Qr)/Qt (ME -2/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
270  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm21", "Charge Ratio (Ql+Qr)/Qt (ME -2/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
271  hRHRatioQ.push_back(
272  ibooker.book1D("hRHRatioQm11a", "Charge Ratio (Ql+Qr)/Qt (ME -1/1a); (Ql+Qr)/Qt", 100, -0.1, 1.1));
273  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm13", "Charge Ratio (Ql+Qr)/Qt (ME -1/3); (Ql+Qr)/Qt", 100, -0.1, 1.1));
274  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQm12", "Charge Ratio (Ql+Qr)/Qt (ME -1/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
275  hRHRatioQ.push_back(
276  ibooker.book1D("hRHRatioQm11b", "Charge Ratio (Ql+Qr)/Qt (ME -1/1b); (Ql+Qr)/Qt", 100, -0.1, 1.1));
277  hRHRatioQ.push_back(
278  ibooker.book1D("hRHRatioQp11b", "Charge Ratio (Ql+Qr)/Qt (ME +1/1b); (Ql+Qr)/Qt", 100, -0.1, 1.1));
279  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp12", "Charge Ratio (Ql+Qr)/Qt (ME +1/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
280  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp13", "Charge Ratio (Ql+Qr)/Qt (ME +1/3); (Ql+Qr)/Qt", 100, -0.1, 1.1));
281  hRHRatioQ.push_back(
282  ibooker.book1D("hRHRatioQp11a", "Charge Ratio (Ql+Qr)/Qt (ME +1/1a); (Ql+Qr)/Qt", 100, -0.1, 1.1));
283  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp21", "Charge Ratio (Ql+Qr)/Qt (ME +2/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
284  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp22", "Charge Ratio (Ql+Qr)/Qt (ME +2/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
285  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp31", "Charge Ratio (Ql+Qr)/Qt (ME +3/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
286  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp32", "Charge Ratio (Ql+Qr)/Qt (ME +3/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
287  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp41", "Charge Ratio (Ql+Qr)/Qt (ME +4/1); (Ql+Qr)/Qt", 100, -0.1, 1.1));
288  hRHRatioQ.push_back(ibooker.book1D("hRHRatioQp42", "Charge Ratio (Ql+Qr)/Qt (ME +4/2); (Ql+Qr)/Qt", 100, -0.1, 1.1));
289  hRHTiming.push_back(ibooker.book1D("hRHTimingm42", "recHit Time (ME -4/2); ns", 200, -500., 500.));
290  hRHTiming.push_back(ibooker.book1D("hRHTimingm41", "recHit Time (ME -4/1); ns", 200, -500., 500.));
291  hRHTiming.push_back(ibooker.book1D("hRHTimingm32", "recHit Time (ME -3/2); ns", 200, -500., 500.));
292  hRHTiming.push_back(ibooker.book1D("hRHTimingm31", "recHit Time (ME -3/1); ns", 200, -500., 500.));
293  hRHTiming.push_back(ibooker.book1D("hRHTimingm22", "recHit Time (ME -2/2); ns", 200, -500., 500.));
294  hRHTiming.push_back(ibooker.book1D("hRHTimingm21", "recHit Time (ME -2/1); ns", 200, -500., 500.));
295  hRHTiming.push_back(ibooker.book1D("hRHTimingm11a", "recHit Time (ME -1/1a); ns", 200, -500., 500.));
296  hRHTiming.push_back(ibooker.book1D("hRHTimingm13", "recHit Time (ME -1/3); ns", 200, -500., 500.));
297  hRHTiming.push_back(ibooker.book1D("hRHTimingm12", "recHit Time (ME -1/2); ns", 200, -500., 500.));
298  hRHTiming.push_back(ibooker.book1D("hRHTimingm11b", "recHit Time (ME -1/1b); ns", 200, -500., 500.));
299  hRHTiming.push_back(ibooker.book1D("hRHTimingp11b", "recHit Time (ME +1/1b); ns", 200, -500., 500.));
300  hRHTiming.push_back(ibooker.book1D("hRHTimingp12", "recHit Time (ME +1/2); ns", 200, -500., 500.));
301  hRHTiming.push_back(ibooker.book1D("hRHTimingp13", "recHit Time (ME +1/3); ns", 200, -500., 500.));
302  hRHTiming.push_back(ibooker.book1D("hRHTimingp11a", "recHit Time (ME +1/1a); ns", 200, -500., 500.));
303  hRHTiming.push_back(ibooker.book1D("hRHTimingp21", "recHit Time (ME +2/1); ns", 200, -500., 500.));
304  hRHTiming.push_back(ibooker.book1D("hRHTimingp22", "recHit Time (ME +2/2); ns", 200, -500., 500.));
305  hRHTiming.push_back(ibooker.book1D("hRHTimingp31", "recHit Time (ME +3/1); ns", 200, -500., 500.));
306  hRHTiming.push_back(ibooker.book1D("hRHTimingp32", "recHit Time (ME +3/2); ns", 200, -500., 500.));
307  hRHTiming.push_back(ibooker.book1D("hRHTimingp41", "recHit Time (ME +4/1); ns", 200, -500., 500.));
308  hRHTiming.push_back(ibooker.book1D("hRHTimingp42", "recHit Time (ME +4/2); ns", 200, -500., 500.));
309  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem42", "Anode recHit Time (ME -4/2); ns", 80, -500., 500.));
310  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem41", "Anode recHit Time (ME -4/1); ns", 80, -500., 500.));
311  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem32", "Anode recHit Time (ME -3/2); ns", 80, -500., 500.));
312  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem31", "Anode recHit Time (ME -3/1); ns", 80, -500., 500.));
313  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem22", "Anode recHit Time (ME -2/2); ns", 80, -500., 500.));
314  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem21", "Anode recHit Time (ME -2/1); ns", 80, -500., 500.));
315  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem11a", "Anode recHit Time (ME -1/1a); ns", 80, -500., 500.));
316  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem13", "Anode recHit Time (ME -1/3); ns", 80, -500., 500.));
317  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem12", "Anode recHit Time (ME -1/2); ns", 80, -500., 500.));
318  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodem11b", "Anode recHit Time (ME -1/1b); ns", 80, -500., 500.));
319  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep11b", "Anode recHit Time (ME +1/1b); ns", 80, -500., 500.));
320  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep12", "Anode recHit Time (ME +1/2); ns", 80, -500., 500.));
321  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep13", "Anode recHit Time (ME +1/3); ns", 80, -500., 500.));
322  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep11a", "Anode recHit Time (ME +1/1a); ns", 80, -500., 500.));
323  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep21", "Anode recHit Time (ME +2/1); ns", 80, -500., 500.));
324  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep22", "Anode recHit Time (ME +2/2); ns", 80, -500., 500.));
325  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep31", "Anode recHit Time (ME +3/1); ns", 80, -500., 500.));
326  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep32", "Anode recHit Time (ME +3/2); ns", 80, -500., 500.));
327  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep41", "Anode recHit Time (ME +4/1); ns", 80, -500., 500.));
328  hRHTimingAnode.push_back(ibooker.book1D("hRHTimingAnodep42", "Anode recHit Time (ME +4/2); ns", 80, -500., 500.));
329  hRHstpos.push_back(
330  ibooker.book1D("hRHstposm42", "Reconstructed Position on Strip (ME -4/2); Strip Widths", 120, -0.6, 0.6));
331  hRHstpos.push_back(
332  ibooker.book1D("hRHstposm41", "Reconstructed Position on Strip (ME -4/1); Strip Widths", 120, -0.6, 0.6));
333  hRHstpos.push_back(
334  ibooker.book1D("hRHstposm32", "Reconstructed Position on Strip (ME -3/2); Strip Widths", 120, -0.6, 0.6));
335  hRHstpos.push_back(
336  ibooker.book1D("hRHstposm31", "Reconstructed Position on Strip (ME -3/1); Strip Widths", 120, -0.6, 0.6));
337  hRHstpos.push_back(
338  ibooker.book1D("hRHstposm22", "Reconstructed Position on Strip (ME -2/2); Strip Widths", 120, -0.6, 0.6));
339  hRHstpos.push_back(
340  ibooker.book1D("hRHstposm21", "Reconstructed Position on Strip (ME -2/1); Strip Widths", 120, -0.6, 0.6));
341  hRHstpos.push_back(
342  ibooker.book1D("hRHstposm11a", "Reconstructed Position on Strip (ME -1/1a); Strip Widths", 120, -0.6, 0.6));
343  hRHstpos.push_back(
344  ibooker.book1D("hRHstposm13", "Reconstructed Position on Strip (ME -1/3); Strip Widths", 120, -0.6, 0.6));
345  hRHstpos.push_back(
346  ibooker.book1D("hRHstposm12", "Reconstructed Position on Strip (ME -1/2); Strip Widths", 120, -0.6, 0.6));
347  hRHstpos.push_back(
348  ibooker.book1D("hRHstposm11b", "Reconstructed Position on Strip (ME -1/1b); Strip Widths", 120, -0.6, 0.6));
349  hRHstpos.push_back(
350  ibooker.book1D("hRHstposp11b", "Reconstructed Position on Strip (ME +1/1b); Strip Widths", 120, -0.6, 0.6));
351  hRHstpos.push_back(
352  ibooker.book1D("hRHstposp12", "Reconstructed Position on Strip (ME +1/2); Strip Widths", 120, -0.6, 0.6));
353  hRHstpos.push_back(
354  ibooker.book1D("hRHstposp13", "Reconstructed Position on Strip (ME +1/3); Strip Widths", 120, -0.6, 0.6));
355  hRHstpos.push_back(
356  ibooker.book1D("hRHstposp11a", "Reconstructed Position on Strip (ME +1/1a); Strip Widths", 120, -0.6, 0.6));
357  hRHstpos.push_back(
358  ibooker.book1D("hRHstposp21", "Reconstructed Position on Strip (ME +2/1); Strip Widths", 120, -0.6, 0.6));
359  hRHstpos.push_back(
360  ibooker.book1D("hRHstposp22", "Reconstructed Position on Strip (ME +2/2); Strip Widths", 120, -0.6, 0.6));
361  hRHstpos.push_back(
362  ibooker.book1D("hRHstposp31", "Reconstructed Position on Strip (ME +3/1); Strip Widths", 120, -0.6, 0.6));
363  hRHstpos.push_back(
364  ibooker.book1D("hRHstposp32", "Reconstructed Position on Strip (ME +3/2); Strip Widths", 120, -0.6, 0.6));
365  hRHstpos.push_back(
366  ibooker.book1D("hRHstposp41", "Reconstructed Position on Strip (ME +4/1); Strip Widths", 120, -0.6, 0.6));
367  hRHstpos.push_back(
368  ibooker.book1D("hRHstposp42", "Reconstructed Position on Strip (ME +4/2); Strip Widths", 120, -0.6, 0.6));
369  hRHsterr.push_back(
370  ibooker.book1D("hRHsterrm42", "Estimated Error on Strip Measurement (ME -4/2); Strip Widths", 75, -0.01, 0.24));
371  hRHsterr.push_back(
372  ibooker.book1D("hRHsterrm41", "Estimated Error on Strip Measurement (ME -4/1); Strip Widths", 75, -0.01, 0.24));
373  hRHsterr.push_back(
374  ibooker.book1D("hRHsterrm32", "Estimated Error on Strip Measurement (ME -3/2); Strip Widths", 75, -0.01, 0.24));
375  hRHsterr.push_back(
376  ibooker.book1D("hRHsterrm31", "Estimated Error on Strip Measurement (ME -3/1); Strip Widths", 75, -0.01, 0.24));
377  hRHsterr.push_back(
378  ibooker.book1D("hRHsterrm22", "Estimated Error on Strip Measurement (ME -2/2); Strip Widths", 75, -0.01, 0.24));
379  hRHsterr.push_back(
380  ibooker.book1D("hRHsterrm21", "Estimated Error on Strip Measurement (ME -2/1); Strip Widths", 75, -0.01, 0.24));
381  hRHsterr.push_back(
382  ibooker.book1D("hRHsterrm11a", "Estimated Error on Strip Measurement (ME -1/1a); Strip Widths", 75, -0.01, 0.24));
383  hRHsterr.push_back(
384  ibooker.book1D("hRHsterrm13", "Estimated Error on Strip Measurement (ME -1/3); Strip Widths", 75, -0.01, 0.24));
385  hRHsterr.push_back(
386  ibooker.book1D("hRHsterrm12", "Estimated Error on Strip Measurement (ME -1/2); Strip Widths", 75, -0.01, 0.24));
387  hRHsterr.push_back(
388  ibooker.book1D("hRHsterrm11b", "Estimated Error on Strip Measurement (ME -1/1b); Strip Widths", 75, -0.01, 0.24));
389  hRHsterr.push_back(
390  ibooker.book1D("hRHsterrp11b", "Estimated Error on Strip Measurement (ME +1/1b); Strip Widths", 75, -0.01, 0.24));
391  hRHsterr.push_back(
392  ibooker.book1D("hRHsterrp12", "Estimated Error on Strip Measurement (ME +1/2); Strip Widths", 75, -0.01, 0.24));
393  hRHsterr.push_back(
394  ibooker.book1D("hRHsterrp13", "Estimated Error on Strip Measurement (ME +1/3); Strip Widths", 75, -0.01, 0.24));
395  hRHsterr.push_back(
396  ibooker.book1D("hRHsterrp11a", "Estimated Error on Strip Measurement (ME +1/1a); Strip Widths", 75, -0.01, 0.24));
397  hRHsterr.push_back(
398  ibooker.book1D("hRHsterrp21", "Estimated Error on Strip Measurement (ME +2/1); Strip Widths", 75, -0.01, 0.24));
399  hRHsterr.push_back(
400  ibooker.book1D("hRHsterrp22", "Estimated Error on Strip Measurement (ME +2/2); Strip Widths", 75, -0.01, 0.24));
401  hRHsterr.push_back(
402  ibooker.book1D("hRHsterrp31", "Estimated Error on Strip Measurement (ME +3/1); Strip Widths", 75, -0.01, 0.24));
403  hRHsterr.push_back(
404  ibooker.book1D("hRHsterrp32", "Estimated Error on Strip Measurement (ME +3/2); Strip Widths", 75, -0.01, 0.24));
405  hRHsterr.push_back(
406  ibooker.book1D("hRHsterrp41", "Estimated Error on Strip Measurement (ME +4/1); Strip Widths", 75, -0.01, 0.24));
407  hRHsterr.push_back(
408  ibooker.book1D("hRHsterrp42", "Estimated Error on Strip Measurement (ME +4/2); Strip Widths", 75, -0.01, 0.24));
409 
410  // segments
411  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/Segments");
412 
413  hSnSegments = ibooker.book1D("hSnSegments", "Segments per Event; # of Segments", 100, 0., 100.); // 1 bin is 1
414 
415  hSnhitsAll = ibooker.book1D("hSnhits", "N hits on Segments; # of hits", 8, -0.5, 7.5);
416  hSnhits.push_back(ibooker.book1D("hSnhitsm42", "# of hits on Segments (ME -4/2); # of hits", 8, -0.5, 7.5));
417  hSnhits.push_back(ibooker.book1D("hSnhitsm41", "# of hits on Segments (ME -4/1); # of hits", 8, -0.5, 7.5));
418  hSnhits.push_back(ibooker.book1D("hSnhitsm32", "# of hits on Segments (ME -3/2); # of hits", 8, -0.5, 7.5));
419  hSnhits.push_back(ibooker.book1D("hSnhitsm31", "# of hits on Segments (ME -3/1); # of hits", 8, -0.5, 7.5));
420  hSnhits.push_back(ibooker.book1D("hSnhitsm22", "# of hits on Segments (ME -2/2); # of hits", 8, -0.5, 7.5));
421  hSnhits.push_back(ibooker.book1D("hSnhitsm21", "# of hits on Segments (ME -2/1); # of hits", 8, -0.5, 7.5));
422  hSnhits.push_back(ibooker.book1D("hSnhitsm11a", "# of hits on Segments (ME -1/1a); # of hits", 8, -0.5, 7.5));
423  hSnhits.push_back(ibooker.book1D("hSnhitsm13", "# of hits on Segments (ME -1/3); # of hits", 8, -0.5, 7.5));
424  hSnhits.push_back(ibooker.book1D("hSnhitsm12", "# of hits on Segments (ME -1/2); # of hits", 8, -0.5, 7.5));
425  hSnhits.push_back(ibooker.book1D("hSnhitsm11b", "# of hits on Segments (ME -1/1b); # of hits", 8, -0.5, 7.5));
426  hSnhits.push_back(ibooker.book1D("hSnhitsp11b", "# of hits on Segments (ME +1/1b); # of hits", 8, -0.5, 7.5));
427  hSnhits.push_back(ibooker.book1D("hSnhitsp12", "# of hits on Segments (ME +1/2); # of hits", 8, -0.5, 7.5));
428  hSnhits.push_back(ibooker.book1D("hSnhitsp13", "# of hits on Segments (ME +1/3); # of hits", 8, -0.5, 7.5));
429  hSnhits.push_back(ibooker.book1D("hSnhitsp11a", "# of hits on Segments (ME +1/1a); # of hits", 8, -0.5, 7.5));
430  hSnhits.push_back(ibooker.book1D("hSnhitsp21", "# of hits on Segments (ME +2/1); # of hits", 8, -0.5, 7.5));
431  hSnhits.push_back(ibooker.book1D("hSnhitsp22", "# of hits on Segments (ME +2/2); # of hits", 8, -0.5, 7.5));
432  hSnhits.push_back(ibooker.book1D("hSnhitsp31", "# of hits on Segments (ME +3/1); # of hits", 8, -0.5, 7.5));
433  hSnhits.push_back(ibooker.book1D("hSnhitsp32", "# of hits on Segments (ME +3/2); # of hits", 8, -0.5, 7.5));
434  hSnhits.push_back(ibooker.book1D("hSnhitsp41", "# of hits on Segments (ME +4/1); # of hits", 8, -0.5, 7.5));
435  hSnhits.push_back(ibooker.book1D("hSnhitsp42", "# of hits on Segments (ME +4/2); # of hits", 8, -0.5, 7.5));
436  hSChiSqAll = ibooker.book1D("hSChiSq", "Segment Normalized Chi2; Chi2/ndof", 110, -0.05, 10.5);
437  hSChiSq.push_back(ibooker.book1D("hSChiSqm42", "Segment Normalized Chi2 (ME -4/2); Chi2/ndof", 110, -0.05, 10.5));
438  hSChiSq.push_back(ibooker.book1D("hSChiSqm41", "Segment Normalized Chi2 (ME -4/1); Chi2/ndof", 110, -0.05, 10.5));
439  hSChiSq.push_back(ibooker.book1D("hSChiSqm32", "Segment Normalized Chi2 (ME -3/2); Chi2/ndof", 110, -0.05, 10.5));
440  hSChiSq.push_back(ibooker.book1D("hSChiSqm31", "Segment Normalized Chi2 (ME -3/1); Chi2/ndof", 110, -0.05, 10.5));
441  hSChiSq.push_back(ibooker.book1D("hSChiSqm22", "Segment Normalized Chi2 (ME -2/2); Chi2/ndof", 110, -0.05, 10.5));
442  hSChiSq.push_back(ibooker.book1D("hSChiSqm21", "Segment Normalized Chi2 (ME -2/1); Chi2/ndof", 110, -0.05, 10.5));
443  hSChiSq.push_back(ibooker.book1D("hSChiSqm11a", "Segment Normalized Chi2 (ME -1/1a); Chi2/ndof", 110, -0.05, 10.5));
444  hSChiSq.push_back(ibooker.book1D("hSChiSqm13", "Segment Normalized Chi2 (ME -1/3); Chi2/ndof", 110, -0.05, 10.5));
445  hSChiSq.push_back(ibooker.book1D("hSChiSqm12", "Segment Normalized Chi2 (ME -1/2); Chi2/ndof", 110, -0.05, 10.5));
446  hSChiSq.push_back(ibooker.book1D("hSChiSqm11b", "Segment Normalized Chi2 (ME -1/1b); Chi2/ndof", 110, -0.05, 10.5));
447  hSChiSq.push_back(ibooker.book1D("hSChiSqp11b", "Segment Normalized Chi2 (ME +1/1b); Chi2/ndof", 110, -0.05, 10.5));
448  hSChiSq.push_back(ibooker.book1D("hSChiSqp12", "Segment Normalized Chi2 (ME +1/2); Chi2/ndof", 110, -0.05, 10.5));
449  hSChiSq.push_back(ibooker.book1D("hSChiSqp13", "Segment Normalized Chi2 (ME +1/3); Chi2/ndof", 110, -0.05, 10.5));
450  hSChiSq.push_back(ibooker.book1D("hSChiSqp11a", "Segment Normalized Chi2 (ME +1/1a); Chi2/ndof", 110, -0.05, 10.5));
451  hSChiSq.push_back(ibooker.book1D("hSChiSqp21", "Segment Normalized Chi2 (ME +2/1); Chi2/ndof", 110, -0.05, 10.5));
452  hSChiSq.push_back(ibooker.book1D("hSChiSqp22", "Segment Normalized Chi2 (ME +2/2); Chi2/ndof", 110, -0.05, 10.5));
453  hSChiSq.push_back(ibooker.book1D("hSChiSqp31", "Segment Normalized Chi2 (ME +3/1); Chi2/ndof", 110, -0.05, 10.5));
454  hSChiSq.push_back(ibooker.book1D("hSChiSqp32", "Segment Normalized Chi2 (ME +3/2); Chi2/ndof", 110, -0.05, 10.5));
455  hSChiSq.push_back(ibooker.book1D("hSChiSqp41", "Segment Normalized Chi2 (ME +4/1); Chi2/ndof", 110, -0.05, 10.5));
456  hSChiSq.push_back(ibooker.book1D("hSChiSqp42", "Segment Normalized Chi2 (ME +4/2); Chi2/ndof", 110, -0.05, 10.5));
457  hSChiSqProbAll = ibooker.book1D("hSChiSqProb", "Segment chi2 Probability; Probability", 110, -0.05, 1.05);
458  hSChiSqProb.push_back(
459  ibooker.book1D("hSChiSqProbm42", "Segment chi2 Probability (ME -4/2); Probability", 110, -0.05, 1.05));
460  hSChiSqProb.push_back(
461  ibooker.book1D("hSChiSqProbm41", "Segment chi2 Probability (ME -4/1); Probability", 110, -0.05, 1.05));
462  hSChiSqProb.push_back(
463  ibooker.book1D("hSChiSqProbm32", "Segment chi2 Probability (ME -3/2); Probability", 110, -0.05, 1.05));
464  hSChiSqProb.push_back(
465  ibooker.book1D("hSChiSqProbm31", "Segment chi2 Probability (ME -3/1); Probability", 110, -0.05, 1.05));
466  hSChiSqProb.push_back(
467  ibooker.book1D("hSChiSqProbm22", "Segment chi2 Probability (ME -2/2); Probability", 110, -0.05, 1.05));
468  hSChiSqProb.push_back(
469  ibooker.book1D("hSChiSqProbm21", "Segment chi2 Probability (ME -2/1); Probability", 110, -0.05, 1.05));
470  hSChiSqProb.push_back(
471  ibooker.book1D("hSChiSqProbm11a", "Segment chi2 Probability (ME -1/1a); Probability", 110, -0.05, 1.05));
472  hSChiSqProb.push_back(
473  ibooker.book1D("hSChiSqProbm13", "Segment chi2 Probability (ME -1/3); Probability", 110, -0.05, 1.05));
474  hSChiSqProb.push_back(
475  ibooker.book1D("hSChiSqProbm12", "Segment chi2 Probability (ME -1/2); Probability", 110, -0.05, 1.05));
476  hSChiSqProb.push_back(
477  ibooker.book1D("hSChiSqProbm11b", "Segment chi2 Probability (ME -1/1b); Probability", 110, -0.05, 1.05));
478  hSChiSqProb.push_back(
479  ibooker.book1D("hSChiSqProbp11b", "Segment chi2 Probability (ME +1/1b); Probability", 110, -0.05, 1.05));
480  hSChiSqProb.push_back(
481  ibooker.book1D("hSChiSqProbp12", "Segment chi2 Probability (ME +1/2); Probability", 110, -0.05, 1.05));
482  hSChiSqProb.push_back(
483  ibooker.book1D("hSChiSqProbp13", "Segment chi2 Probability (ME +1/3); Probability", 110, -0.05, 1.05));
484  hSChiSqProb.push_back(
485  ibooker.book1D("hSChiSqProbp11a", "Segment chi2 Probability (ME +1/1a); Probability", 110, -0.05, 1.05));
486  hSChiSqProb.push_back(
487  ibooker.book1D("hSChiSqProbp21", "Segment chi2 Probability (ME +2/1); Probability", 110, -0.05, 1.05));
488  hSChiSqProb.push_back(
489  ibooker.book1D("hSChiSqProbp22", "Segment chi2 Probability (ME +2/2); Probability", 110, -0.05, 1.05));
490  hSChiSqProb.push_back(
491  ibooker.book1D("hSChiSqProbp31", "Segment chi2 Probability (ME +3/1); Probability", 110, -0.05, 1.05));
492  hSChiSqProb.push_back(
493  ibooker.book1D("hSChiSqProbp32", "Segment chi2 Probability (ME +3/2); Probability", 110, -0.05, 1.05));
494  hSChiSqProb.push_back(
495  ibooker.book1D("hSChiSqProbp41", "Segment chi2 Probability (ME +4/1); Probability", 110, -0.05, 1.05));
496  hSChiSqProb.push_back(
497  ibooker.book1D("hSChiSqProbp42", "Segment chi2 Probability (ME +4/2); Probability", 110, -0.05, 1.05));
498  hSGlobalTheta =
499  ibooker.book1D("hSGlobalTheta", "Segment Direction (Global Theta); Global Theta (radians)", 136, -0.1, 3.3);
500  hSGlobalPhi = ibooker.book1D("hSGlobalPhi", "Segment Direction (Global Phi); Global Phi (radians)", 128, -3.2, 3.2);
501 
502  hSTimeDiff = ibooker.book1D("hSTimeDiff", "Anode Minus Cathode Segment Time [ns]", 50, -50, 50);
503  hSTimeDiffByChamberType.push_back(
504  ibooker.book1D("hSTimeDiff_m42", "Anode Minus Cathode Segment Time (ME -4/2) [ns]", 50, -50, 50));
505  hSTimeDiffByChamberType.push_back(
506  ibooker.book1D("hSTimeDiff_m41", "Anode Minus Cathode Segment Time (ME -4/1) [ns]", 50, -50, 50));
507  hSTimeDiffByChamberType.push_back(
508  ibooker.book1D("hSTimeDiff_m32", "Anode Minus Cathode Segment Time (ME -3/2) [ns]", 50, -50, 50));
509  hSTimeDiffByChamberType.push_back(
510  ibooker.book1D("hSTimeDiff_m31", "Anode Minus Cathode Segment Time (ME -3/2) [ns]", 50, -50, 50));
511  hSTimeDiffByChamberType.push_back(
512  ibooker.book1D("hSTimeDiff_m22", "Anode Minus Cathode Segment Time (ME -2/2) [ns]", 50, -50, 50));
513  hSTimeDiffByChamberType.push_back(
514  ibooker.book1D("hSTimeDiff_m21", "Anode Minus Cathode Segment Time (ME -2/1) [ns]", 50, -50, 50));
515  hSTimeDiffByChamberType.push_back(
516  ibooker.book1D("hSTimeDiff_m11a", "Anode Minus Cathode Segment Time (ME -1/1a) [ns]", 50, -50, 50));
517  hSTimeDiffByChamberType.push_back(
518  ibooker.book1D("hSTimeDiff_m13", "Anode Minus Cathode Segment Time (ME -1/3) [ns]", 50, -50, 50));
519  hSTimeDiffByChamberType.push_back(
520  ibooker.book1D("hSTimeDiff_m12", "Anode Minus Cathode Segment Time (ME -1/2) [ns]", 50, -50, 50));
521  hSTimeDiffByChamberType.push_back(
522  ibooker.book1D("hSTimeDiff_m11b", "Anode Minus Cathode Segment Time (ME -1/1b) [ns]", 50, -50, 50));
523  hSTimeDiffByChamberType.push_back(
524  ibooker.book1D("hSTimeDiff_p11b", "Anode Minus Cathode Segment Time (ME +1/1b) [ns]", 50, -50, 50));
525  hSTimeDiffByChamberType.push_back(
526  ibooker.book1D("hSTimeDiff_p12", "Anode Minus Cathode Segment Time (ME +1/2) [ns]", 50, -50, 50));
527  hSTimeDiffByChamberType.push_back(
528  ibooker.book1D("hSTimeDiff_p13", "Anode Minus Cathode Segment Time (ME +1/3) [ns]", 50, -50, 50));
529  hSTimeDiffByChamberType.push_back(
530  ibooker.book1D("hSTimeDiff_p11a", "Anode Minus Cathode Segment Time (ME +1/1a) [ns]", 50, -50, 50));
531  hSTimeDiffByChamberType.push_back(
532  ibooker.book1D("hSTimeDiff_p21", "Anode Minus Cathode Segment Time (ME +2/1) [ns]", 50, -50, 50));
533  hSTimeDiffByChamberType.push_back(
534  ibooker.book1D("hSTimeDiff_p22", "Anode Minus Cathode Segment Time (ME +2/2) [ns]", 50, -50, 50));
535  hSTimeDiffByChamberType.push_back(
536  ibooker.book1D("hSTimeDiff_p31", "Anode Minus Cathode Segment Time (ME +3/1) [ns]", 50, -50, 50));
537  hSTimeDiffByChamberType.push_back(
538  ibooker.book1D("hSTimeDiff_p32", "Anode Minus Cathode Segment Time (ME +3/2) [ns]", 50, -50, 50));
539  hSTimeDiffByChamberType.push_back(
540  ibooker.book1D("hSTimeDiff_p41", "Anode Minus Cathode Segment Time (ME +4/1) [ns]", 50, -50, 50));
541  hSTimeDiffByChamberType.push_back(
542  ibooker.book1D("hSTimeDiff_p42", "Anode Minus Cathode Segment Time (ME +4/2) [ns]", 50, -50, 50));
543 
544  hSTimeAnode = ibooker.book1D("hSTimeAnode", "Anode Only Segment Time [ns]", 200, -200, 200);
545  hSTimeAnodeByChamberType.push_back(
546  ibooker.book1D("hSTimeAnode_m42", "Anode Only Segment Time (ME -4/2) [ns]", 200, -200, 200));
547  hSTimeAnodeByChamberType.push_back(
548  ibooker.book1D("hSTimeAnode_m41", "Anode Only Segment Time (ME -4/1) [ns]", 200, -200, 200));
549  hSTimeAnodeByChamberType.push_back(
550  ibooker.book1D("hSTimeAnode_m32", "Anode Only Segment Time (ME -3/2) [ns]", 200, -200, 200));
551  hSTimeAnodeByChamberType.push_back(
552  ibooker.book1D("hSTimeAnode_m31", "Anode Only Segment Time (ME -3/2) [ns]", 200, -200, 200));
553  hSTimeAnodeByChamberType.push_back(
554  ibooker.book1D("hSTimeAnode_m22", "Anode Only Segment Time (ME -2/2) [ns]", 200, -200, 200));
555  hSTimeAnodeByChamberType.push_back(
556  ibooker.book1D("hSTimeAnode_m21", "Anode Only Segment Time (ME -2/1) [ns]", 200, -200, 200));
557  hSTimeAnodeByChamberType.push_back(
558  ibooker.book1D("hSTimeAnode_m11a", "Anode Only Segment Time (ME -1/1a) [ns]", 200, -200, 200));
559  hSTimeAnodeByChamberType.push_back(
560  ibooker.book1D("hSTimeAnode_m13", "Anode Only Segment Time (ME -1/3) [ns]", 200, -200, 200));
561  hSTimeAnodeByChamberType.push_back(
562  ibooker.book1D("hSTimeAnode_m12", "Anode Only Segment Time (ME -1/2) [ns]", 200, -200, 200));
563  hSTimeAnodeByChamberType.push_back(
564  ibooker.book1D("hSTimeAnode_m11b", "Anode Only Segment Time (ME -1/1b) [ns]", 200, -200, 200));
565  hSTimeAnodeByChamberType.push_back(
566  ibooker.book1D("hSTimeAnode_p11b", "Anode Only Segment Time (ME +1/1b) [ns]", 200, -200, 200));
567  hSTimeAnodeByChamberType.push_back(
568  ibooker.book1D("hSTimeAnode_p12", "Anode Only Segment Time (ME +1/2) [ns]", 200, -200, 200));
569  hSTimeAnodeByChamberType.push_back(
570  ibooker.book1D("hSTimeAnode_p13", "Anode Only Segment Time (ME +1/3) [ns]", 200, -200, 200));
571  hSTimeAnodeByChamberType.push_back(
572  ibooker.book1D("hSTimeAnode_p11a", "Anode Only Segment Time (ME +1/1a) [ns]", 200, -200, 200));
573  hSTimeAnodeByChamberType.push_back(
574  ibooker.book1D("hSTimeAnode_p21", "Anode Only Segment Time (ME +2/1) [ns]", 200, -200, 200));
575  hSTimeAnodeByChamberType.push_back(
576  ibooker.book1D("hSTimeAnode_p22", "Anode Only Segment Time (ME +2/2) [ns]", 200, -200, 200));
577  hSTimeAnodeByChamberType.push_back(
578  ibooker.book1D("hSTimeAnode_p31", "Anode Only Segment Time (ME +3/1) [ns]", 200, -200, 200));
579  hSTimeAnodeByChamberType.push_back(
580  ibooker.book1D("hSTimeAnode_p32", "Anode Only Segment Time (ME +3/2) [ns]", 200, -200, 200));
581  hSTimeAnodeByChamberType.push_back(
582  ibooker.book1D("hSTimeAnode_p41", "Anode Only Segment Time (ME +4/1) [ns]", 200, -200, 200));
583  hSTimeAnodeByChamberType.push_back(
584  ibooker.book1D("hSTimeAnode_p42", "Anode Only Segment Time (ME +4/2) [ns]", 200, -200, 200));
585 
586  hSTimeCathode = ibooker.book1D("hSTimeCathode", "Cathode Only Segment Time [ns]", 200, -200, 200);
587  hSTimeCathodeByChamberType.push_back(
588  ibooker.book1D("hSTimeCathode_m42", "Cathode Only Segment Time (ME -4/2) [ns]", 200, -200, 200));
589  hSTimeCathodeByChamberType.push_back(
590  ibooker.book1D("hSTimeCathode_m41", "Cathode Only Segment Time (ME -4/1) [ns]", 200, -200, 200));
591  hSTimeCathodeByChamberType.push_back(
592  ibooker.book1D("hSTimeCathode_m32", "Cathode Only Segment Time (ME -3/2) [ns]", 200, -200, 200));
593  hSTimeCathodeByChamberType.push_back(
594  ibooker.book1D("hSTimeCathode_m31", "Cathode Only Segment Time (ME -3/2) [ns]", 200, -200, 200));
595  hSTimeCathodeByChamberType.push_back(
596  ibooker.book1D("hSTimeCathode_m22", "Cathode Only Segment Time (ME -2/2) [ns]", 200, -200, 200));
597  hSTimeCathodeByChamberType.push_back(
598  ibooker.book1D("hSTimeCathode_m21", "Cathode Only Segment Time (ME -2/1) [ns]", 200, -200, 200));
599  hSTimeCathodeByChamberType.push_back(
600  ibooker.book1D("hSTimeCathode_m11a", "Cathode Only Segment Time (ME -1/1a) [ns]", 200, -200, 200));
601  hSTimeCathodeByChamberType.push_back(
602  ibooker.book1D("hSTimeCathode_m13", "Cathode Only Segment Time (ME -1/3) [ns]", 200, -200, 200));
603  hSTimeCathodeByChamberType.push_back(
604  ibooker.book1D("hSTimeCathode_m12", "Cathode Only Segment Time (ME -1/2) [ns]", 200, -200, 200));
605  hSTimeCathodeByChamberType.push_back(
606  ibooker.book1D("hSTimeCathode_m11b", "Cathode Only Segment Time (ME -1/1b) [ns]", 200, -200, 200));
607  hSTimeCathodeByChamberType.push_back(
608  ibooker.book1D("hSTimeCathode_p11b", "Cathode Only Segment Time (ME +1/1b) [ns]", 200, -200, 200));
609  hSTimeCathodeByChamberType.push_back(
610  ibooker.book1D("hSTimeCathode_p12", "Cathode Only Segment Time (ME +1/2) [ns]", 200, -200, 200));
611  hSTimeCathodeByChamberType.push_back(
612  ibooker.book1D("hSTimeCathode_p13", "Cathode Only Segment Time (ME +1/3) [ns]", 200, -200, 200));
613  hSTimeCathodeByChamberType.push_back(
614  ibooker.book1D("hSTimeCathode_p11a", "Cathode Only Segment Time (ME +1/1a) [ns]", 200, -200, 200));
615  hSTimeCathodeByChamberType.push_back(
616  ibooker.book1D("hSTimeCathode_p21", "Cathode Only Segment Time (ME +2/1) [ns]", 200, -200, 200));
617  hSTimeCathodeByChamberType.push_back(
618  ibooker.book1D("hSTimeCathode_p22", "Cathode Only Segment Time (ME +2/2) [ns]", 200, -200, 200));
619  hSTimeCathodeByChamberType.push_back(
620  ibooker.book1D("hSTimeCathode_p31", "Cathode Only Segment Time (ME +3/1) [ns]", 200, -200, 200));
621  hSTimeCathodeByChamberType.push_back(
622  ibooker.book1D("hSTimeCathode_p32", "Cathode Only Segment Time (ME +3/2) [ns]", 200, -200, 200));
623  hSTimeCathodeByChamberType.push_back(
624  ibooker.book1D("hSTimeCathode_p41", "Cathode Only Segment Time (ME +4/1) [ns]", 200, -200, 200));
625  hSTimeCathodeByChamberType.push_back(
626  ibooker.book1D("hSTimeCathode_p42", "Cathode Only Segment Time (ME +4/2) [ns]", 200, -200, 200));
627 
628  hSTimeCombined = ibooker.book1D("hSTimeCombined", "Segment Time (anode+cathode times) [ns]", 200, -200, 200);
629  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
630  "hSTimeCombined_m42", "Segment Time (anode+cathode times) Segment Time (ME -4/2) [ns]", 200, -200, 200));
631  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
632  "hSTimeCombined_m41", "Segment Time (anode+cathode times) Segment Time (ME -4/1) [ns]", 200, -200, 200));
633  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
634  "hSTimeCombined_m32", "Segment Time (anode+cathode times) Segment Time (ME -3/2) [ns]", 200, -200, 200));
635  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
636  "hSTimeCombined_m31", "Segment Time (anode+cathode times) Segment Time (ME -3/2) [ns]", 200, -200, 200));
637  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
638  "hSTimeCombined_m22", "Segment Time (anode+cathode times) Segment Time (ME -2/2) [ns]", 200, -200, 200));
639  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
640  "hSTimeCombined_m21", "Segment Time (anode+cathode times) Segment Time (ME -2/1) [ns]", 200, -200, 200));
641  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
642  "hSTimeCombined_m11a", "Segment Time (anode+cathode times) Segment Time (ME -1/1a) [ns]", 200, -200, 200));
643  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
644  "hSTimeCombined_m13", "Segment Time (anode+cathode times) Segment Time (ME -1/3) [ns]", 200, -200, 200));
645  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
646  "hSTimeCombined_m12", "Segment Time (anode+cathode times) Segment Time (ME -1/2) [ns]", 200, -200, 200));
647  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
648  "hSTimeCombined_m11b", "Segment Time (anode+cathode times) Segment Time (ME -1/1b) [ns]", 200, -200, 200));
649  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
650  "hSTimeCombined_p11b", "Segment Time (anode+cathode times) Segment Time (ME +1/1b) [ns]", 200, -200, 200));
651  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
652  "hSTimeCombined_p12", "Segment Time (anode+cathode times) Segment Time (ME +1/2) [ns]", 200, -200, 200));
653  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
654  "hSTimeCombined_p13", "Segment Time (anode+cathode times) Segment Time (ME +1/3) [ns]", 200, -200, 200));
655  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
656  "hSTimeCombined_p11a", "Segment Time (anode+cathode times) Segment Time (ME +1/1a) [ns]", 200, -200, 200));
657  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
658  "hSTimeCombined_p21", "Segment Time (anode+cathode times) Segment Time (ME +2/1) [ns]", 200, -200, 200));
659  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
660  "hSTimeCombined_p22", "Segment Time (anode+cathode times) Segment Time (ME +2/2) [ns]", 200, -200, 200));
661  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
662  "hSTimeCombined_p31", "Segment Time (anode+cathode times) Segment Time (ME +3/1) [ns]", 200, -200, 200));
663  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
664  "hSTimeCombined_p32", "Segment Time (anode+cathode times) Segment Time (ME +3/2) [ns]", 200, -200, 200));
665  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
666  "hSTimeCombined_p41", "Segment Time (anode+cathode times) Segment Time (ME +4/1) [ns]", 200, -200, 200));
667  hSTimeCombinedByChamberType.push_back(ibooker.book1D(
668  "hSTimeCombined_p42", "Segment Time (anode+cathode times) Segment Time (ME +4/2) [ns]", 200, -200, 200));
669 
671  ibooker.book2D("hSTimeDiffSerial", "Anode Minus Cathode Segment Time [ns]", 601, -0.5, 600.5, 200, -50, 50);
673  ibooker.book2D("hSTimeAnodeSerial", "Anode Only Segment Time [ns]", 601, -0.5, 600.5, 200, -200, 200);
675  ibooker.book2D("hSTimeCathodeSerial", "Cathode Only Segment Time [ns]", 601, -0.5, 600.5, 200, -200, 200);
676  hSTimeCombinedSerial = ibooker.book2D(
677  "hSTimeCombinedSerial", "Segment Time (anode+cathode times) [ns]", 601, -0.5, 600.5, 200, -200, 200);
678 
679  hSTimeVsZ = ibooker.book2D("hSTimeVsZ", "Segment Time vs. Z; [ns] vs. [cm]", 200, -1200, 1200, 200, -200, 200);
680  hSTimeVsTOF =
681  ibooker.book2D("hSTimeVsTOF", "Segment Time vs. Distance from IP; [ns] vs. [cm]", 180, 500, 1400, 200, -200, 200);
682 
683  // resolution
684  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/Resolution");
685 
686  hSResid.push_back(ibooker.book1D(
687  "hSResidm42", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -4/2); Strip Widths", 100, -0.5, 0.5));
688  hSResid.push_back(ibooker.book1D(
689  "hSResidm41", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -4/1); Strip Widths", 100, -0.5, 0.5));
690  hSResid.push_back(ibooker.book1D(
691  "hSResidm32", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -3/2); Strip Widths", 100, -0.5, 0.5));
692  hSResid.push_back(ibooker.book1D(
693  "hSResidm31", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -3/1); Strip Widths", 100, -0.5, 0.5));
694  hSResid.push_back(ibooker.book1D(
695  "hSResidm22", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -2/2); Strip Widths", 100, -0.5, 0.5));
696  hSResid.push_back(ibooker.book1D(
697  "hSResidm21", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -2/1); Strip Widths", 100, -0.5, 0.5));
698  hSResid.push_back(ibooker.book1D(
699  "hSResidm11a", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/1a); Strip Widths", 100, -0.5, 0.5));
700  hSResid.push_back(ibooker.book1D(
701  "hSResidm13", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/3); Strip Widths", 100, -0.5, 0.5));
702  hSResid.push_back(ibooker.book1D(
703  "hSResidm12", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/2); Strip Widths", 100, -0.5, 0.5));
704  hSResid.push_back(ibooker.book1D(
705  "hSResidm11b", "Fitted Position on Strip - Reconstructed for Layer 3 (ME -1/1b); Strip Widths", 100, -0.5, 0.5));
706  hSResid.push_back(ibooker.book1D(
707  "hSResidp11b", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/1b); Strip Widths", 100, -0.5, 0.5));
708  hSResid.push_back(ibooker.book1D(
709  "hSResidp12", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/2); Strip Widths", 100, -0.5, 0.5));
710  hSResid.push_back(ibooker.book1D(
711  "hSResidp13", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/3); Strip Widths", 100, -0.5, 0.5));
712  hSResid.push_back(ibooker.book1D(
713  "hSResidp11a", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +1/1a); Strip Widths", 100, -0.5, 0.5));
714  hSResid.push_back(ibooker.book1D(
715  "hSResidp21", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +2/1); Strip Widths", 100, -0.5, 0.5));
716  hSResid.push_back(ibooker.book1D(
717  "hSResidp22", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +2/2); Strip Widths", 100, -0.5, 0.5));
718  hSResid.push_back(ibooker.book1D(
719  "hSResidp31", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +3/1); Strip Widths", 100, -0.5, 0.5));
720  hSResid.push_back(ibooker.book1D(
721  "hSResidp32", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +3/2); Strip Widths", 100, -0.5, 0.5));
722  hSResid.push_back(ibooker.book1D(
723  "hSResidp41", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +4/1); Strip Widths", 100, -0.5, 0.5));
724  hSResid.push_back(ibooker.book1D(
725  "hSResidp42", "Fitted Position on Strip - Reconstructed for Layer 3 (ME +4/2); Strip Widths", 100, -0.5, 0.5));
726 
727  // efficiency
728  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/Efficiency");
729 
730  // hSSTE = ibooker.book1D("hSSTE","hSSTE",40,0.5,40.5);
731  // hRHSTE = ibooker.book1D("hRHSTE","hRHSTE",40,0.5,40.5);
732  hSnum = ibooker.book1D("hSnum", "CSC w rechits in 2+ layers && segment(s)", 20, 0.5, 20.5);
733  hSden = ibooker.book1D("hSden", "CSC w rechits in 2+ layers", 20, 0.5, 20.5);
734  hRHnum = ibooker.book1D("hRHnum", "CSC w segment(s) && rechits in 6 layers", 20, 0.5, 20.5);
735  hRHden = ibooker.book1D("hRHden", "CSC w segment(s)", 20, 0.5, 20.5);
740 
741  // hSEff = ibooker.book1D("hSEff","Segment Efficiency",20,0.5,20.5);
742  // hRHEff = ibooker.book1D("hRHEff","recHit Efficiency",20,0.5,20.5);
743  hSSTE2 = ibooker.book2D("hSSTE2", "hSSTE2", 36, 0.5, 36.5, 20, 0.5, 20.5);
744  hRHSTE2 = ibooker.book2D("hRHSTE2", "hRHSTE2", 36, 0.5, 36.5, 20, 0.5, 20.5);
745  hStripSTE2 = ibooker.book2D("hStripSTE2", "hStripSTE2", 36, 0.5, 36.5, 20, 0.5, 20.5);
746  hWireSTE2 = ibooker.book2D("hWireSTE2", "hWireSTE2", 36, 0.5, 36.5, 20, 0.5, 20.5);
747  hEffDenominator = ibooker.book2D("hEffDenominator", "hEffDenominator", 36, 0.5, 36.5, 20, 0.5, 20.5);
748  // hSEff2 = ibooker.book2D("hSEff2","Segment Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
749  // hRHEff2 = ibooker.book2D("hRHEff2","recHit Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
750  // hStripReadoutEff2 = ibooker.book2D("hStripReadoutEff2","strip readout ratio [(strip+clct+wires)/(clct+wires)] 2D",36,0.5,36.5, 20, 0.5, 20.5);
751  // hStripReadoutEff2->setAxisTitle("Chamber #");
752  // hStripEff2 = ibooker.book2D("hStripEff2","strip Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
753  // hWireEff2 = ibooker.book2D("hWireEff2","wire Efficiency 2D",36,0.5,36.5, 18, 0.5, 18.5);
755  ibooker.book2D("hSensitiveAreaEvt", "Events Passing Selection for Efficiency", 36, 0.5, 36.5, 20, 0.5, 20.5);
756 
757  // bx monitor for trigger synchronization
758  ibooker.setCurrentFolder("CSC/CSCOfflineMonitor/BXMonitor");
759 
760  hALCTgetBX = ibooker.book1D("hALCTgetBX", "ALCT position in ALCT-L1A match window [BX]", 7, -0.5, 6.5);
761  // hALCTgetBXChamberMeans = ibooker.book1D("hALCTgetBXChamberMeans","Chamber Mean ALCT position in ALCT-L1A match window [BX]",60,0,6);
763  ibooker.book2D("hALCTgetBXSerial", "ALCT position in ALCT-L1A match window [BX]", 601, -0.5, 600.5, 7, -0.5, 6.5);
764  hALCTgetBXSerial->setAxisTitle("Chamber Serial Number");
765  hALCTgetBX2DNumerator = ibooker.book2D(
766  "hALCTgetBX2DNumerator", "ALCT position in ALCT-L1A match window [BX] (sum)", 36, 0.5, 36.5, 20, 0.5, 20.5);
767  // hALCTgetBX2DMeans = ibooker.book2D("hALCTgetBX2DMeans","ALCT position in ALCT-L1A match window [BX]",36,0.5,36.5,20,0.5,20.5);
769  ibooker.book2D("hALCTgetBX2Denominator", "Number of ALCT Digis checked", 36, 0.5, 36.5, 20, 0.5, 20.5);
770  // hALCTgetBX2DMeans->setAxisTitle("Chamber #");
771  hALCTgetBX2Denominator->setAxisTitle("Chamber #");
772  hALCTMatch = ibooker.book1D("hALCTMatch", "ALCT position in ALCT-CLCT match window [BX]", 7, -0.5, 6.5);
773  // hALCTMatchChamberMeans = ibooker.book1D("hALCTMatchChamberMeans","Chamber Mean ALCT position in ALCT-CLCT match window [BX]",60,0,6);
774  hALCTMatchSerial = ibooker.book2D(
775  "hALCTMatchSerial", "ALCT position in ALCT-CLCT match window [BX]", 601, -0.5, 600.5, 7, -0.5, 6.5);
776  hALCTMatchSerial->setAxisTitle("Chamber Serial Number");
777  hALCTMatch2DNumerator = ibooker.book2D(
778  "hALCTMatch2DNumerator", "ALCT position in ALCT-CLCT match window [BX] (sum)", 36, 0.5, 36.5, 20, 0.5, 20.5);
779  // hALCTMatch2DMeans = ibooker.book2D("hALCTMatch2DMeans","ALCT position in ALCT-CLCT match window [BX]",36,0.5,36.5,20,0.5,20.5);
781  ibooker.book2D("hALCTMatch2Denominator", "Number of ALCT-CLCT matches checked", 36, 0.5, 36.5, 20, 0.5, 20.5);
782  // hALCTMatch2DMeans->setAxisTitle("Chamber #");
783  hALCTMatch2Denominator->setAxisTitle("Chamber #");
784  hCLCTL1A = ibooker.book1D("hCLCTL1A", "L1A - CLCTpreTrigger at TMB [BX]", 40, 149.5, 189.5);
785  // hCLCTL1AChamberMeans = ibooker.book1D("hCLCTL1AChamberMeans","Chamber Mean L1A - CLCTpreTrigger at TMB [BX]",90,150,159);
787  ibooker.book2D("hCLCTL1ASerial", "L1A - CLCTpreTrigger at TMB [BX]", 601, -0.5, 600.5, 40, 149.5, 189.5);
788  hCLCTL1ASerial->setAxisTitle("Chamber Serial Number");
790  ibooker.book2D("hCLCTL1A2DNumerator", "L1A - CLCTpreTrigger at TMB [BX] (sum)", 36, 0.5, 36.5, 20, 0.5, 20.5);
791  // hCLCTL1A2DMeans = ibooker.book2D("hCLCTL1A2DMeans","L1A - CLCTpreTrigger at TMB [BX]",36,0.5,36.5,20,0.5,20.5);
793  ibooker.book2D("hCLCTL1A2Denominator", "Number of TMB CLCTs checked", 36, 0.5, 36.5, 20, 0.5, 20.5);
794 
795  // labels
802  // applyCSClabels(hSEff, EXTENDED, X);
803  // applyCSClabels(hRHEff, EXTENDED, X);
804  // applyCSClabels(hSEff2, SMALL, Y);
807  // applyCSClabels(hRHEff2, SMALL, Y);
809  // applyCSClabels(hStripReadoutEff2, EXTENDED, Y);
810  // applyCSClabels(hStripEff2, SMALL, Y);
812  // applyCSClabels(hWireEff2, SMALL, Y);
815  // applyCSClabels(hALCTgetBX2DMeans, EXTENDED, Y);
817  // applyCSClabels(hALCTMatch2DMeans, EXTENDED, Y);
819  // applyCSClabels(hCLCTL1A2DMeans, EXTENDED, Y);
821 }
MonitorElement * hEffDenominator
MonitorElement * hOSegmentsSerial
MonitorElement * hRHden
std::vector< MonitorElement * > hSTimeCathodeByChamberType
MonitorElement * hOWireSerial
MonitorElement * hSensitiveAreaEvt
MonitorElement * hOStrips
std::vector< MonitorElement * > hSTimeAnodeByChamberType
std::vector< MonitorElement * > hSTimeDiffByChamberType
std::vector< MonitorElement * > hSResid
MonitorElement * hORecHits
virtual void setCurrentFolder(std::string const &fullpath)
Definition: DQMStore.cc:32
std::vector< MonitorElement * > hRHSumQ
MonitorElement * hStripSTE2
std::vector< MonitorElement * > hWireNumber
std::vector< MonitorElement * > hRHGlobal
MonitorElement * hALCTMatch2DNumerator
MonitorElement * hORecHitsSerial
MonitorElement * hSTimeAnodeSerial
MonitorElement * hWirenGroupsTotal
MonitorElement * hCLCTL1ASerial
MonitorElement * hOStripSerial
std::vector< MonitorElement * > hStripNumber
MonitorElement * hSSTE2
MonitorElement * hWireSTE2
MonitorElement * hSTimeAnode
MonitorElement * hSGlobalPhi
std::vector< MonitorElement * > hSnhits
MonitorElement * hOWires
MonitorElement * hSnSegments
MonitorElement * hOStripsAndWiresAndCLCT
MonitorElement * hOSegments
std::vector< MonitorElement * > hRHstpos
MonitorElement * hALCTMatchSerial
MonitorElement * hSnhitsAll
MonitorElement * hRHnrechitsHi
MonitorElement * hALCTgetBX
MonitorElement * hALCTMatch
std::vector< MonitorElement * > hSChiSq
MonitorElement * hSGlobalTheta
MonitorElement * hSTimeDiffSerial
MonitorElement * hSTimeCombined
MonitorElement * hOWiresAndCLCT
MonitorElement * hSden
MonitorElement * hCLCTL1A2Denominator
std::vector< MonitorElement * > hSTimeCombinedByChamberType
MonitorElement * hALCTgetBX2Denominator
virtual 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)
MonitorElement * hSTimeVsZ
MonitorElement * hRHSTE2
MonitorElement * hSChiSqAll
MonitorElement * hCSCOccupancy
std::vector< MonitorElement * > hWireTBin
MonitorElement * hCLCTL1A2DNumerator
std::vector< MonitorElement * > hRHTiming
MonitorElement * hALCTgetBX2DNumerator
MonitorElement * book2D(TString const &name, TString const &title, int nchX, double lowX, double highX, int nchY, double lowY, double highY, FUNC onbooking=NOOP())
Definition: DQMStore.h:212
MonitorElement * hALCTMatch2Denominator
MonitorElement * hCLCTL1A
std::vector< MonitorElement * > hRHTimingAnode
std::vector< MonitorElement * > hRHRatioQ
std::vector< MonitorElement * > hRHsterr
MonitorElement * hSTimeDiff
MonitorElement * hSTimeCathode
std::vector< MonitorElement * > hSChiSqProb
MonitorElement * hSTimeCathodeSerial
MonitorElement * hWirenGroupsTotalHi
MonitorElement * hStripNFired
MonitorElement * hSTimeCombinedSerial
std::vector< MonitorElement * > hStripPed
MonitorElement * hALCTgetBXSerial
MonitorElement * hSTimeVsTOF
MonitorElement * hRHnrechits
MonitorElement * hSnum
MonitorElement * book1D(TString const &name, TString const &title, int const nchX, double const lowX, double const highX, FUNC onbooking=NOOP())
Definition: DQMStore.h:98
MonitorElement * hStripNFiredHi
MonitorElement * hRHnum
MonitorElement * hSChiSqProbAll
void applyCSClabels(MonitorElement *meHisto, LabelType t, AxisType a)
virtual void setAxisTitle(const std::string &title, int axis=1)
set x-, y- or z-axis title (axis=1, 2, 3 respectively)

◆ chamberSerial()

int CSCOfflineMonitor::chamberSerial ( CSCDetId  id)
private

Definition at line 2118 of file CSCOfflineMonitor.cc.

Referenced by doBXMonitor(), doOccupancies(), and doSegments().

2118  {
2119  int st = id.station();
2120  int ri = id.ring();
2121  int ch = id.chamber();
2122  int ec = id.endcap();
2123  int kSerial = ch;
2124  if (st == 1 && ri == 1)
2125  kSerial = ch;
2126  if (st == 1 && ri == 2)
2127  kSerial = ch + 36;
2128  if (st == 1 && ri == 3)
2129  kSerial = ch + 72;
2130  if (st == 1 && ri == 4)
2131  kSerial = ch;
2132  if (st == 2 && ri == 1)
2133  kSerial = ch + 108;
2134  if (st == 2 && ri == 2)
2135  kSerial = ch + 126;
2136  if (st == 3 && ri == 1)
2137  kSerial = ch + 162;
2138  if (st == 3 && ri == 2)
2139  kSerial = ch + 180;
2140  if (st == 4 && ri == 1)
2141  kSerial = ch + 216;
2142  if (st == 4 && ri == 2)
2143  kSerial = ch + 234; // from 2014
2144  if (ec == 2)
2145  kSerial = kSerial + 300;
2146  return kSerial;
2147 }

◆ doBXMonitor()

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 1784 of file CSCOfflineMonitor.cc.

References CSCTMBHeader::ALCTMatchTime(), CSCTMBHeader::BXNCount(), CSCDetId::chamber(), chamberSerial(), RPCNoise_example::check, CSCDCCExaminer::check(), CSCDCCExaminer::crcALCT(), CSCDCCExaminer::crcCFEB(), CSCDCCExaminer::crcTMB(), FEDRawData::data(), data, CSCDCCEventData::dduData(), CSCCrateMap::detId(), CSCDCCExaminer::errors(), options_cfi::eventSetup, FEDRawDataCollection::FEDData(), dqm::impl::MonitorElement::Fill(), hALCTgetBX, hALCTgetBX2Denominator, hALCTgetBX2DNumerator, hALCTgetBXSerial, hALCTMatch, hALCTMatch2Denominator, hALCTMatch2DNumerator, hALCTMatchSerial, hCLCTL1A, hCLCTL1A2Denominator, hCLCTL1A2DNumerator, hCLCTL1ASerial, hcrateToken_, mps_fire::i, triggerObjects_cff::id, dqmiolumiharvest::j, phase1PixelTopology::layer, LogTrace, FEDNumbering::MAXCSCDDUFEDID, FEDNumbering::MAXCSCFEDID, FEDNumbering::MINCSCDDUFEDID, FEDNumbering::MINCSCFEDID, edm::ESHandle< T >::product(), FastTimerService_cff::range, rd_token, CSCDCCExaminer::setMask(), FEDRawData::size(), and typeIndex().

Referenced by analyze().

1787  {
1788  // Loop over ALCTDigis
1789 
1790  for (CSCALCTDigiCollection::DigiRangeIterator j = alcts->begin(); j != alcts->end(); j++) {
1791  const CSCDetId& idALCT = (*j).first;
1792  const CSCALCTDigiCollection::Range& range = (*j).second;
1793  for (CSCALCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
1794  // Valid digi in the chamber (or in neighbouring chamber)
1795  if ((*digiIt).isValid()) {
1796  hALCTgetBX->Fill((*digiIt).getBX());
1797  hALCTgetBXSerial->Fill(chamberSerial(idALCT), (*digiIt).getBX());
1798  hALCTgetBX2DNumerator->Fill(idALCT.chamber(), typeIndex(idALCT, 2), (*digiIt).getBX());
1799  hALCTgetBX2Denominator->Fill(idALCT.chamber(), typeIndex(idALCT, 2));
1800  }
1801  }
1802  } // end ALCT Digi loop
1803 
1804  // Loop over raw data to get TMBHeader information
1805  // Taking code from EventFilter/CSCRawToDigis/CSCDCCUnpacker.cc
1807 
1808  hcrate = eventSetup.getHandle(hcrateToken_);
1809 
1810  const CSCCrateMap* pcrate = hcrate.product();
1811 
1812  // Try to get raw data
1814  if (!(event.getByToken(rd_token, rawdata))) {
1815  edm::LogWarning("CSCOfflineMonitor") << " FEDRawDataCollection not available";
1816  return;
1817  }
1818 
1819  bool goodEvent = false;
1820  unsigned long dccBinCheckMask = 0x06080016;
1821  unsigned int examinerMask = 0x1FEBF3F6;
1822  unsigned int errorMask = 0x0;
1823 
1824  // For new CSC readout layout, which doesn't include DCCs need to loop over DDU FED IDs.
1825  // DCC IDs are included for backward compatibility with old data
1826  std::vector<unsigned int> cscFEDids;
1827 
1828  for (unsigned int id = FEDNumbering::MINCSCFEDID; id <= FEDNumbering::MAXCSCFEDID; ++id) // loop over DCCs
1829  {
1830  cscFEDids.push_back(id);
1831  }
1832 
1833  for (unsigned int id = FEDNumbering::MINCSCDDUFEDID; id <= FEDNumbering::MAXCSCDDUFEDID; ++id) // loop over DDUs
1834  {
1835  cscFEDids.push_back(id);
1836  }
1837 
1838  for (unsigned int i = 0; i < cscFEDids.size(); i++) // loop over all CSC FEDs (DCCs and DDUs)
1839  {
1840  unsigned int id = cscFEDids[i];
1841  bool isDDU_FED = ((id >= FEDNumbering::MINCSCDDUFEDID) && (id <= FEDNumbering::MAXCSCDDUFEDID)) ? true : false;
1842 
1845 
1847  const FEDRawData& fedData = rawdata->FEDData(id);
1848  unsigned long length = fedData.size();
1849 
1850  if (length >= 32) {
1851  CSCDCCExaminer* examiner = nullptr;
1852  std::stringstream examiner_out, examiner_err;
1853  goodEvent = true;
1854  examiner = new CSCDCCExaminer();
1855  if (examinerMask & 0x40000)
1856  examiner->crcCFEB(true);
1857  if (examinerMask & 0x8000)
1858  examiner->crcTMB(true);
1859  if (examinerMask & 0x0400)
1860  examiner->crcALCT(true);
1861  examiner->setMask(examinerMask);
1862  const short unsigned int* data = (short unsigned int*)fedData.data();
1863 
1864  int res = examiner->check(data, long(fedData.size() / 2));
1865  if (res < 0) {
1866  goodEvent = false;
1867  } else {
1868  goodEvent = !(examiner->errors() & dccBinCheckMask);
1869  }
1870 
1871  if (goodEvent) {
1873 
1874  CSCDCCExaminer* ptrExaminer = examiner;
1875 
1876  std::vector<CSCDDUEventData> fed_Data;
1877  std::vector<CSCDDUEventData>* ptr_fedData = &fed_Data;
1878 
1879  if (isDDU_FED) // Use new DDU FED readout mode
1880  {
1881  CSCDDUEventData single_dduData((short unsigned int*)fedData.data(), ptrExaminer);
1882  fed_Data.push_back(single_dduData);
1883 
1884  } else // Use old DCC FED readout mode
1885  {
1886  CSCDCCEventData dccData((short unsigned int*)fedData.data(), ptrExaminer);
1887  fed_Data = dccData.dduData();
1888  }
1889 
1891  const std::vector<CSCDDUEventData>& dduData = *ptr_fedData;
1892 
1894  CSCDetId layer(1, 1, 1, 1, 1);
1895  for (unsigned int iDDU = 0; iDDU < dduData.size(); ++iDDU) { // loop over DDUs
1898  if (dduData[iDDU].trailer().errorstat() & errorMask) {
1899  LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "DDU# " << iDDU << " has serious error - no digis unpacked! "
1900  << std::hex << dduData[iDDU].trailer().errorstat();
1901  continue; // to next iteration of DDU loop
1902  }
1903 
1905  const std::vector<CSCEventData>& cscData = dduData[iDDU].cscData();
1906 
1907  for (unsigned int iCSC = 0; iCSC < cscData.size(); ++iCSC) { // loop over CSCs
1908 
1910  int vmecrate = cscData[iCSC].dmbHeader()->crateID();
1911  int dmb = cscData[iCSC].dmbHeader()->dmbID();
1912 
1913  int icfeb = 0;
1914  int ilayer = 0;
1915 
1916  if ((vmecrate >= 1) && (vmecrate <= 60) && (dmb >= 1) && (dmb <= 10) && (dmb != 6)) {
1917  layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
1918  } else {
1919  LogTrace("CSCOfflineMonitor") << " detID input out of range!!! ";
1920  LogTrace("CSCOfflineMonitor") << " skipping chamber vme= " << vmecrate << " dmb= " << dmb;
1921  continue; // to next iteration of iCSC loop
1922  }
1923 
1925  int nalct = cscData[iCSC].dmbHeader()->nalct();
1926  bool goodALCT = false;
1927  //if (nalct&&(cscData[iCSC].dataPresent>>6&0x1)==1) {
1928  if (nalct && cscData[iCSC].alctHeader()) {
1929  if (cscData[iCSC].alctHeader()->check()) {
1930  goodALCT = true;
1931  }
1932  }
1933 
1935  int nclct = cscData[iCSC].dmbHeader()->nclct();
1936  bool goodTMB = false;
1937  if (nclct && cscData[iCSC].tmbData()) {
1938  if (cscData[iCSC].tmbHeader()->check()) {
1939  if (cscData[iCSC].comparatorData()->check())
1940  goodTMB = true;
1941  }
1942  }
1943 
1944  if (goodTMB && goodALCT) {
1945  const CSCTMBHeader* tmbHead = cscData[iCSC].tmbHeader();
1946  std::vector<CSCCLCTDigi> clcts = cscData[iCSC].tmbHeader()->CLCTDigis(layer.rawId());
1947  if (clcts.empty() || !(clcts[0].isValid()))
1948  continue;
1949  // Check if the CLCT was in ME11a (ring 4)
1950  if (layer.station() == 1 && layer.ring() == 1 && clcts[0].getKeyStrip() > 128) {
1951  layer = CSCDetId(layer.endcap(), layer.station(), 4, layer.chamber());
1952  }
1953  hALCTMatch->Fill(tmbHead->ALCTMatchTime());
1955  // Only fill big 2D display if ALCTMatchTime !=6, since this bin is polluted by the CLCT only triggers
1956  // One will have to look at the serial plots to see if the are a lot of entries here
1957  if (tmbHead->ALCTMatchTime() != 6) {
1958  hALCTMatch2DNumerator->Fill(layer.chamber(), typeIndex(layer, 2), tmbHead->ALCTMatchTime());
1959  hALCTMatch2Denominator->Fill(layer.chamber(), typeIndex(layer, 2));
1960  }
1961 
1962  int TMB_CLCTpre_rel_L1A = tmbHead->BXNCount() - clcts[0].getFullBX();
1963  if (TMB_CLCTpre_rel_L1A > 3563)
1964  TMB_CLCTpre_rel_L1A = TMB_CLCTpre_rel_L1A - 3564;
1965  if (TMB_CLCTpre_rel_L1A < 0)
1966  TMB_CLCTpre_rel_L1A = TMB_CLCTpre_rel_L1A + 3564;
1967 
1968  hCLCTL1A->Fill(TMB_CLCTpre_rel_L1A);
1969  hCLCTL1ASerial->Fill(chamberSerial(layer), TMB_CLCTpre_rel_L1A);
1970  hCLCTL1A2DNumerator->Fill(layer.chamber(), typeIndex(layer, 2), TMB_CLCTpre_rel_L1A);
1971  hCLCTL1A2Denominator->Fill(layer.chamber(), typeIndex(layer, 2));
1972 
1973  } // end if goodTMB and goodALCT
1974  } // end loop CSCData
1975  } // end loop DDU
1976  } // end if good event
1977  if (examiner != nullptr)
1978  delete examiner;
1979  } // end if non-zero fed data
1980  } // end DCC loop for NON-REFERENCE
1981 
1982  return;
1983 }
01/20/05 A.Tumanov
void crcCFEB(bool enable)
const edm::ESGetToken< CSCCrateMap, CSCCrateMapRcd > hcrateToken_
int chamberSerial(CSCDetId id)
MonitorElement * hALCTMatch2DNumerator
size_t size() const
Lenght of the data buffer in bytes.
Definition: FEDRawData.h:45
MonitorElement * hCLCTL1ASerial
void crcALCT(bool enable)
Definition: Electron.h:6
#define LogTrace(id)
constexpr std::array< uint8_t, layerIndexSize > layer
void Fill(long long x)
uint16_t ALCTMatchTime() const
Definition: CSCTMBHeader.h:44
const std::vector< CSCDDUEventData > & dduData() const
accessor to dduData
T const * product() const
Definition: ESHandle.h:86
uint16_t BXNCount() const
Definition: CSCTMBHeader.h:43
edm::EDGetTokenT< FEDRawDataCollection > rd_token
MonitorElement * hALCTMatchSerial
int typeIndex(CSCDetId id, int flag=1)
MonitorElement * hALCTgetBX
MonitorElement * hALCTMatch
void crcTMB(bool enable)
int chamber() const
Definition: CSCDetId.h:62
MonitorElement * hCLCTL1A2Denominator
MonitorElement * hALCTgetBX2Denominator
const FEDRawData & FEDData(int fedid) const
retrieve data for fed
CSCDetId detId(int vme, int dmb, int cfeb, int layer=0) const
Definition: CSCCrateMap.cc:9
MonitorElement * hCLCTL1A2DNumerator
MonitorElement * hALCTgetBX2DNumerator
std::pair< const_iterator, const_iterator > Range
MonitorElement * hALCTMatch2Denominator
std::vector< DigiType >::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:79
ExaminerStatusType errors(void) const
const unsigned char * data() const
Return a const pointer to the beginning of the data buffer.
Definition: FEDRawData.cc:24
MonitorElement * hALCTgetBXSerial
Log< level::Warning, false > LogWarning
void setMask(ExaminerMaskType mask)
Definition: event.py:1

◆ doEfficiencies()

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 1492 of file CSCOfflineMonitor.cc.

References newFWLiteAna::bin, CSCDetId::chamber(), CSCGeometry::chamber(), CSCGeometry::chambers(), CSCChamberSpecs::chamberType(), dtChamberEfficiency_cfi::cscSegments, change_name::diff, CSCDetId::endcap(), extrapolate1D(), dqm::impl::MonitorElement::Fill(), first, dqmMemoryStats::float, cms::cuda::for(), CSCLayer::geometry(), hEffDenominator, hRHden, hRHnum, hRHSTE2, hSden, hSensitiveAreaEvt, hSnum, hSSTE2, hStripSTE2, hWireSTE2, CSCDetId::iChamberType(), CSCChamber::id(), createfilelist::int, CSCChamber::layer(), CSCDetId::layer(), lineParametrization(), CSCSegment::localDirection(), CSCSegment::localPosition(), TrapezoidalPlaneBounds::parameters(), FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), CSCChamber::specs(), CSCDetId::station(), DigiDM_cff::strips, remoteMonitoring_LASER_era2018_cfg::threshold, GeomDet::toGlobal(), GeomDet::toLocal(), parallelization::uint, mps_merge::weight, DigiDM_cff::wires, withinSensitiveRegion(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), PV3DBase< T, PVType, FrameType >::z(), and CSCDetId::zendcap().

Referenced by analyze().

1496  {
1497  bool allWires[2][4][4][36][6];
1498  bool allStrips[2][4][4][36][6];
1499  bool AllRecHits[2][4][4][36][6];
1500  bool AllSegments[2][4][4][36];
1501 
1502  //bool MultiSegments[2][4][4][36];
1503  for (int iE = 0; iE < 2; iE++) {
1504  for (int iS = 0; iS < 4; iS++) {
1505  for (int iR = 0; iR < 4; iR++) {
1506  for (int iC = 0; iC < 36; iC++) {
1507  AllSegments[iE][iS][iR][iC] = false;
1508  //MultiSegments[iE][iS][iR][iC] = false;
1509  for (int iL = 0; iL < 6; iL++) {
1510  allWires[iE][iS][iR][iC][iL] = false;
1511  allStrips[iE][iS][iR][iC][iL] = false;
1512  AllRecHits[iE][iS][iR][iC][iL] = false;
1513  }
1514  }
1515  }
1516  }
1517  }
1518 
1519  // Wires
1520  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
1521  CSCDetId idrec = (CSCDetId)(*dWDiter).first;
1522  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
1523  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
1524  for (; wireIter != lWire; ++wireIter) {
1525  allWires[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1526  true;
1527  break;
1528  }
1529  }
1530 
1531  //---- STRIPS
1532  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
1533  CSCDetId idrec = (CSCDetId)(*dSDiter).first;
1534  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
1535  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
1536  for (; stripIter != lStrip; ++stripIter) {
1537  std::vector<int> myADCVals = stripIter->getADCCounts();
1538  bool thisStripFired = false;
1539  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1540  float threshold = 13.3;
1541  float diff = 0.;
1542  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
1543  diff = (float)myADCVals[iCount] - thisPedestal;
1544  if (diff > threshold) {
1545  thisStripFired = true;
1546  break;
1547  }
1548  }
1549  if (thisStripFired) {
1550  allStrips[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1551  true;
1552  break;
1553  }
1554  }
1555  }
1556 
1557  // Rechits
1558  for (CSCRecHit2DCollection::const_iterator recEffIt = recHits->begin(); recEffIt != recHits->end(); recEffIt++) {
1559  //CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
1560  CSCDetId idrec = (CSCDetId)(*recEffIt).cscDetId();
1561  AllRecHits[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1562  true;
1563  }
1564 
1565  std::vector<uint> seg_ME2(2, 0);
1566  std::vector<uint> seg_ME3(2, 0);
1567  std::vector<pair<CSCDetId, CSCSegment> > theSegments(4);
1568  // Segments
1569  for (CSCSegmentCollection::const_iterator segEffIt = cscSegments->begin(); segEffIt != cscSegments->end();
1570  segEffIt++) {
1571  CSCDetId idseg = (CSCDetId)(*segEffIt).cscDetId();
1572  //if(AllSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()]){
1573  //MultiSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()] = true;
1574  //}
1575  AllSegments[idseg.endcap() - 1][idseg.station() - 1][idseg.ring() - 1][idseg.chamber() - 1] = true;
1576  // "Intrinsic" efficiency measurement relies on "good" segment extrapolation - we need the pre-selection below
1577  // station 2 "good" segment will be used for testing efficiencies in ME1 and ME3
1578  // station 3 "good" segment will be used for testing efficiencies in ME2 and ME4
1579  if (2 == idseg.station() || 3 == idseg.station()) {
1580  uint seg_tmp;
1581  if (2 == idseg.station()) {
1582  ++seg_ME2[idseg.endcap() - 1];
1583  seg_tmp = seg_ME2[idseg.endcap() - 1];
1584  } else {
1585  ++seg_ME3[idseg.endcap() - 1];
1586  seg_tmp = seg_ME3[idseg.endcap() - 1];
1587  }
1588  // is the segment good
1589  if (1 == seg_tmp && 6 == (*segEffIt).nRecHits() && (*segEffIt).chi2() / (*segEffIt).degreesOfFreedom() < 3.) {
1590  pair<CSCDetId, CSCSegment> specSeg = make_pair((CSCDetId)(*segEffIt).cscDetId(), *segEffIt);
1591  theSegments[2 * (idseg.endcap() - 1) + (idseg.station() - 2)] = specSeg;
1592  }
1593  }
1594  /*
1595  if(2==idseg.station()){
1596  ++seg_ME2[idseg.endcap() -1];
1597  if(1==seg_ME2[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1598  pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1599  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1600  }
1601  }
1602  else if(3==idseg.station()){
1603  ++seg_ME3[idseg.endcap() -1];
1604  if(1==seg_ME3[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1605  pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1606  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1607  }
1608  }
1609  */
1610  }
1611  // Simple efficiency calculations
1612  for (int iE = 0; iE < 2; iE++) {
1613  for (int iS = 0; iS < 4; iS++) {
1614  for (int iR = 0; iR < 4; iR++) {
1615  for (int iC = 0; iC < 36; iC++) {
1616  int NumberOfLayers = 0;
1617  for (int iL = 0; iL < 6; iL++) {
1618  if (AllRecHits[iE][iS][iR][iC][iL]) {
1619  NumberOfLayers++;
1620  }
1621  }
1622 
1623  // set bin = 1-10 for ME-42, ME-41,...ME-11B, ME-11A,
1624  // 11-20 for ME+11A, ME+11B, ... ME+41, ME+42
1625  int bin = CSCDetId::iChamberType(iS + 1, iR + 1); // 1-10 for ME11A...ME42
1626  if (iE > 0) { // in this loop iE=1 is -z endcap
1627  bin = 11 - bin;
1628  } else { // in this loop iE=0 is +z endcap
1629  bin += 10;
1630  }
1631 
1632  if (NumberOfLayers > 1) {
1633  //if(!(MultiSegments[iE][iS][iR][iC])){
1634  if (AllSegments[iE][iS][iR][iC]) {
1635  //---- Efficient segment evenents
1636  hSnum->Fill(bin);
1637  }
1638  //---- All segment events (normalization)
1639  hSden->Fill(bin);
1640  //}
1641  }
1642  if (AllSegments[iE][iS][iR][iC]) {
1643  if (NumberOfLayers == 6) {
1644  //---- Efficient rechit events
1645  hRHnum->Fill(bin);
1646  ;
1647  }
1648  //---- All rechit events (normalization)
1649  hRHden->Fill(bin);
1650  ;
1651  }
1652  }
1653  }
1654  }
1655  }
1656 
1657  // pick a segment only if there are no others in the station
1658  std::vector<pair<CSCDetId, CSCSegment>*> theSeg;
1659  if (1 == seg_ME2[0])
1660  theSeg.push_back(&theSegments[0]);
1661  if (1 == seg_ME3[0])
1662  theSeg.push_back(&theSegments[1]);
1663  if (1 == seg_ME2[1])
1664  theSeg.push_back(&theSegments[2]);
1665  if (1 == seg_ME3[1])
1666  theSeg.push_back(&theSegments[3]);
1667 
1668  if (!theSeg.empty()) {
1669  std::map<int, GlobalPoint> extrapolatedPoint;
1670  std::map<int, GlobalPoint>::iterator it;
1671  const CSCGeometry::ChamberContainer& ChamberContainer = cscGeom->chambers();
1672  // Pick which chamber with which segment to test
1673  for (unsigned int nCh = 0; nCh < ChamberContainer.size(); nCh++) {
1674  const CSCChamber* cscchamber = ChamberContainer[nCh];
1675  pair<CSCDetId, CSCSegment>* thisSegment = nullptr;
1676  for (uint iSeg = 0; iSeg < theSeg.size(); ++iSeg) {
1677  if (cscchamber->id().endcap() == theSeg[iSeg]->first.endcap()) {
1678  if (1 == cscchamber->id().station() || 3 == cscchamber->id().station()) {
1679  if (2 == theSeg[iSeg]->first.station()) {
1680  thisSegment = theSeg[iSeg];
1681  }
1682  } else if (2 == cscchamber->id().station() || 4 == cscchamber->id().station()) {
1683  if (3 == theSeg[iSeg]->first.station()) {
1684  thisSegment = theSeg[iSeg];
1685  }
1686  }
1687  }
1688  }
1689  // this chamber is to be tested with thisSegment
1690  if (thisSegment) {
1691  CSCSegment* seg = &(thisSegment->second);
1692  const CSCChamber* segChamber = cscGeom->chamber(thisSegment->first);
1693  LocalPoint localCenter(0., 0., 0);
1694  GlobalPoint cscchamberCenter = cscchamber->toGlobal(localCenter);
1695  // try to save some time (extrapolate a segment to a certain position only once)
1696  it = extrapolatedPoint.find(int(cscchamberCenter.z()));
1697  if (it == extrapolatedPoint.end()) {
1698  GlobalPoint segPos = segChamber->toGlobal(seg->localPosition());
1699  GlobalVector segDir = segChamber->toGlobal(seg->localDirection());
1700  double paramaterLine = lineParametrization(segPos.z(), cscchamberCenter.z(), segDir.z());
1701  double xExtrapolated = extrapolate1D(segPos.x(), segDir.x(), paramaterLine);
1702  double yExtrapolated = extrapolate1D(segPos.y(), segDir.y(), paramaterLine);
1703  GlobalPoint globP(xExtrapolated, yExtrapolated, cscchamberCenter.z());
1704  extrapolatedPoint[int(cscchamberCenter.z())] = globP;
1705  }
1706  // Where does the extrapolated point lie in the (tested) chamber local frame? Here:
1707  LocalPoint extrapolatedPointLocal = cscchamber->toLocal(extrapolatedPoint[int(cscchamberCenter.z())]);
1708  const CSCLayer* layer_p = cscchamber->layer(1); //layer 1
1709  const CSCLayerGeometry* layerGeom = layer_p->geometry();
1710  const std::array<const float, 4>& layerBounds = layerGeom->parameters();
1711  float shiftFromEdge = 15.; //cm
1712  float shiftFromDeadZone = 10.;
1713  // is the extrapolated point within a sensitive region
1714  bool pass = withinSensitiveRegion(extrapolatedPointLocal,
1715  layerBounds,
1716  cscchamber->id().station(),
1717  cscchamber->id().ring(),
1718  shiftFromEdge,
1719  shiftFromDeadZone);
1720  if (pass) { // the extrapolation point of the segment lies within sensitive region of that chamber
1721  // how many rechit layers are there in the chamber?
1722  // 0 - maybe the muon died or is deflected at large angle? do not use that case
1723  // 1 - could be noise...
1724  // 2 or more - this is promissing; this is our definition of a reliable signal; use it below
1725  // is other definition better?
1726  int nRHLayers = 0;
1727  for (int iL = 0; iL < 6; ++iL) {
1728  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1729  [cscchamber->id().chamber() - 1][iL]) {
1730  ++nRHLayers;
1731  }
1732  }
1733 
1734  // set verticalScale to 1-10 for ME-42...ME-11A,
1735  // 11-20 for ME+11A...ME+42
1736  float verticalScale =
1737  9. + cscchamber->id().endcap() + (cscchamber->specs()->chamberType()) * (cscchamber->id().zendcap());
1738 
1739  hSensitiveAreaEvt->Fill(float(cscchamber->id().chamber()), verticalScale);
1740  if (nRHLayers > 1) { // this chamber contains a reliable signal
1741  // this is the denominator for all efficiencies
1742  hEffDenominator->Fill(float(cscchamber->id().chamber()), verticalScale);
1743  // Segment efficiency
1744  if (AllSegments[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1745  [cscchamber->id().chamber() - 1]) {
1746  hSSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale));
1747  }
1748 
1749  for (int iL = 0; iL < 6; ++iL) {
1750  float weight = 1. / 6.;
1751  // should account for the weight in the efficiency...
1752  // Rechit efficiency
1753  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1754  [cscchamber->id().chamber() - 1][iL]) {
1755  hRHSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1756  }
1757  // Wire efficiency
1758  if (allWires[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1759  [cscchamber->id().chamber() - 1][iL]) {
1760  // one shold account for the weight in the efficiency...
1761  hWireSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1762  }
1763  // Strip efficiency
1764  if (allStrips[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1765  [cscchamber->id().chamber() - 1][iL]) {
1766  // one shold account for the weight in the efficiency...
1767  hStripSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1768  }
1769  }
1770  }
1771  }
1772  }
1773  }
1774  }
1775  //
1776 }
MonitorElement * hEffDenominator
MonitorElement * hRHden
int chamberType() const
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to the given id.
Definition: CSCChamber.cc:30
MonitorElement * hSensitiveAreaEvt
LocalPoint localPosition() const override
Definition: CSCSegment.h:39
short int zendcap() const
Definition: CSCDetId.h:91
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:100
LocalPoint toLocal(const GlobalPoint &gp) const
Conversion to the R.F. of the GeomDet.
Definition: GeomDet.h:58
T z() const
Definition: PV3DBase.h:61
MonitorElement * hStripSTE2
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
Definition: weight.py:1
int layer() const
Definition: CSCDetId.h:56
MonitorElement * hSSTE2
unsigned short iChamberType() const
Definition: CSCDetId.h:96
MonitorElement * hWireSTE2
const CSCLayerGeometry * geometry() const
Definition: CSCLayer.h:44
void Fill(long long x)
LocalVector localDirection() const override
Local direction.
Definition: CSCSegment.h:42
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
int chamber() const
Definition: CSCDetId.h:62
MonitorElement * hSden
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
MonitorElement * hRHSTE2
int station() const
Definition: CSCDetId.h:79
virtual const std::array< const float, 4 > parameters() const
int endcap() const
Definition: CSCDetId.h:85
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:30
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32
int ring() const
Definition: CSCDetId.h:68
MonitorElement * hSnum
const ChamberContainer & chambers() const
Return a vector of all chambers.
Definition: CSCGeometry.cc:96
double extrapolate1D(double initPosition, double initDirection, double parameterOfTheLine)
double lineParametrization(double z1Position, double z2Position, double z1Direction)
MonitorElement * hRHnum
const CSCChamberSpecs * specs() const
Definition: CSCChamber.h:39
CSCDetId id() const
Get the (concrete) DetId.
Definition: CSCChamber.h:34

◆ doOccupancies()

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 866 of file CSCOfflineMonitor.cc.

References c, CSCDetId::chamber(), chamberSerial(), dtChamberEfficiency_cfi::cscSegments, change_name::diff, MillePedeFileConverter_cfg::e, CSCDetId::endcap(), dqm::impl::MonitorElement::Fill(), dqmMemoryStats::float, hCSCOccupancy, hORecHits, hORecHitsSerial, hOSegments, hOSegmentsSerial, hOStrips, hOStripsAndWiresAndCLCT, hOStripSerial, hOWires, hOWiresAndCLCT, hOWireSerial, dqmiolumiharvest::j, alignCSCRings::r, FastTimerService_cff::range, FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), alignCSCRings::s, CSCDetId::station(), DigiDM_cff::strips, remoteMonitoring_LASER_era2018_cfg::threshold, typeIndex(), and DigiDM_cff::wires.

Referenced by analyze().

870  {
871  bool clcto[2][4][4][36];
872  bool wireo[2][4][4][36];
873  bool stripo[2][4][4][36];
874  bool rechito[2][4][4][36];
875  bool segmento[2][4][4][36];
876 
877  bool hasWires = false;
878  bool hasStrips = false;
879  bool hasRecHits = false;
880  bool hasSegments = false;
881 
882  for (int e = 0; e < 2; e++) {
883  for (int s = 0; s < 4; s++) {
884  for (int r = 0; r < 4; r++) {
885  for (int c = 0; c < 36; c++) {
886  clcto[e][s][r][c] = false;
887  wireo[e][s][r][c] = false;
888  stripo[e][s][r][c] = false;
889  rechito[e][s][r][c] = false;
890  segmento[e][s][r][c] = false;
891  }
892  }
893  }
894  }
895 
896  //clcts
897  for (CSCCLCTDigiCollection::DigiRangeIterator j = clcts->begin(); j != clcts->end(); j++) {
898  CSCDetId id = (CSCDetId)(*j).first;
899  int kEndcap = id.endcap();
900  int kRing = id.ring();
901  int kStation = id.station();
902  int kChamber = id.chamber();
903  const CSCCLCTDigiCollection::Range& range = (*j).second;
904  for (CSCCLCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
905  // Valid digi in the chamber (or in neighbouring chamber)
906  if ((*digiIt).isValid()) {
907  //Check whether this CLCT came from ME11a
908  if (kStation == 1 && kRing == 1 && (*digiIt).getKeyStrip() > 128)
909  kRing = 4;
910  clcto[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
911  }
912  }
913  }
914 
915  //wires
916  for (CSCWireDigiCollection::DigiRangeIterator wi = wires->begin(); wi != wires->end(); wi++) {
917  CSCDetId id = (CSCDetId)(*wi).first;
918  int kEndcap = id.endcap();
919  int kRing = id.ring();
920  int kStation = id.station();
921  int kChamber = id.chamber();
922  std::vector<CSCWireDigi>::const_iterator wireIt = (*wi).second.first;
923  std::vector<CSCWireDigi>::const_iterator lastWire = (*wi).second.second;
924  for (; wireIt != lastWire; ++wireIt) {
925  if (!wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
926  wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
927  hOWires->Fill(kChamber, typeIndex(id, 2));
929  hasWires = true;
930  if (clcto[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1])
931  hOWiresAndCLCT->Fill(kChamber, typeIndex(id, 2));
932  //Also check for a CLCT in ME11a if you're in ME11 already
933  if (kStation == 1 && kRing == 1 && clcto[kEndcap - 1][kStation - 1][3][kChamber - 1]) {
934  CSCDetId idME11a = CSCDetId(kEndcap, kStation, 4, kChamber);
935  hOWiresAndCLCT->Fill(kChamber, typeIndex(idME11a, 2));
936  }
937  }
938  } //end for loop
939  }
940 
941  //strips
942  for (CSCStripDigiCollection::DigiRangeIterator si = strips->begin(); si != strips->end(); si++) {
943  CSCDetId id = (CSCDetId)(*si).first;
944  int kEndcap = id.endcap();
945  int kRing = id.ring();
946  int kStation = id.station();
947  int kChamber = id.chamber();
948  std::vector<CSCStripDigi>::const_iterator stripIt = (*si).second.first;
949  std::vector<CSCStripDigi>::const_iterator lastStrip = (*si).second.second;
950  for (; stripIt != lastStrip; ++stripIt) {
951  std::vector<int> myADCVals = stripIt->getADCCounts();
952  bool thisStripFired = false;
953  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
954  float threshold = 13.3;
955  float diff = 0.;
956  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
957  diff = (float)myADCVals[iCount] - thisPedestal;
958  if (diff > threshold) {
959  thisStripFired = true;
960  }
961  }
962  if (thisStripFired) {
963  if (!stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
964  stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
965  hOStrips->Fill(kChamber, typeIndex(id, 2));
967  hasStrips = true;
968  if (clcto[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
969  // check if there is a wire digi in this chamber too
970  // for ME 1/4 check for a wire in ME 1/1
971  if (wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] ||
972  (kRing == 4 && wireo[kEndcap - 1][kStation - 1][0][kChamber - 1])) {
973  hOStripsAndWiresAndCLCT->Fill(kChamber, typeIndex(id, 2));
974  }
975  } //end clct and wire digi check
976  }
977  } //end if (thisStripFired)
978  }
979  }
980 
981  //rechits
983  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
984  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
985  int kEndcap = idrec.endcap();
986  int kRing = idrec.ring();
987  int kStation = idrec.station();
988  int kChamber = idrec.chamber();
989  if (!rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
990  rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
992  hORecHits->Fill(kChamber, typeIndex(idrec, 2));
993  hasRecHits = true;
994  }
995  }
996 
997  //segments
998  for (CSCSegmentCollection::const_iterator segIt = cscSegments->begin(); segIt != cscSegments->end(); segIt++) {
999  CSCDetId id = (CSCDetId)(*segIt).cscDetId();
1000  int kEndcap = id.endcap();
1001  int kRing = id.ring();
1002  int kStation = id.station();
1003  int kChamber = id.chamber();
1004  if (!segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
1005  segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
1007  hOSegments->Fill(kChamber, typeIndex(id, 2));
1008  hasSegments = true;
1009  }
1010  }
1011 
1012  //Overall CSC Occupancy
1013  hCSCOccupancy->Fill(1);
1014  if (hasWires)
1015  hCSCOccupancy->Fill(3);
1016  if (hasStrips)
1017  hCSCOccupancy->Fill(5);
1018  if (hasWires && hasStrips)
1019  hCSCOccupancy->Fill(7);
1020  if (hasRecHits)
1021  hCSCOccupancy->Fill(9);
1022  if (hasSegments)
1023  hCSCOccupancy->Fill(11);
1024 }
MonitorElement * hOSegmentsSerial
MonitorElement * hOWireSerial
MonitorElement * hOStrips
int chamberSerial(CSCDetId id)
MonitorElement * hORecHits
MonitorElement * hORecHitsSerial
MonitorElement * hOStripSerial
MonitorElement * hOWires
void Fill(long long x)
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
MonitorElement * hOStripsAndWiresAndCLCT
MonitorElement * hOSegments
int typeIndex(CSCDetId id, int flag=1)
int chamber() const
Definition: CSCDetId.h:62
MonitorElement * hOWiresAndCLCT
MonitorElement * hCSCOccupancy
int station() const
Definition: CSCDetId.h:79
std::pair< const_iterator, const_iterator > Range
int endcap() const
Definition: CSCDetId.h:85
std::vector< DigiType >::const_iterator const_iterator
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32
int ring() const
Definition: CSCDetId.h:68

◆ doPedestalNoise()

void CSCOfflineMonitor::doPedestalNoise ( edm::Handle< CSCStripDigiCollection strips,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Definition at line 1095 of file CSCOfflineMonitor.cc.

References dqmMemoryStats::float, CSCGeometry::gangedStrips(), getSignal(), hStripPed, CSCDetId::station(), DigiDM_cff::strips, remoteMonitoring_LASER_era2018_cfg::threshold, and typeIndex().

Referenced by analyze().

1096  {
1097  for (CSCStripDigiCollection::DigiRangeIterator dPNiter = strips->begin(); dPNiter != strips->end(); dPNiter++) {
1098  CSCDetId id = (CSCDetId)(*dPNiter).first;
1099  int kStation = id.station();
1100  int kRing = id.ring();
1101  std::vector<CSCStripDigi>::const_iterator pedIt = (*dPNiter).second.first;
1102  std::vector<CSCStripDigi>::const_iterator lStrip = (*dPNiter).second.second;
1103  for (; pedIt != lStrip; ++pedIt) {
1104  int myStrip = pedIt->getStrip();
1105  std::vector<int> myADCVals = pedIt->getADCCounts();
1106  float TotalADC = getSignal(*strips, id, myStrip);
1107  bool thisStripFired = false;
1108  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1109  float thisSignal =
1110  (1. / 6) * (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1111  float threshold = 13.3;
1112 
1113  // Why is this code block even here? Doesn't use myStrip after setting it (converts channel to strip
1114  // for ganged ME11A
1115  if ((kStation == 1 && kRing == 4) && cscGeom->gangedStrips()) {
1116  kRing = 1;
1117  if (myStrip <= 16)
1118  myStrip += 64; // no trapping for any bizarreness
1119  }
1120 
1121  if (TotalADC > threshold) {
1122  thisStripFired = true;
1123  }
1124  if (!thisStripFired) {
1125  float ADC = thisSignal - thisPedestal;
1126  hStripPed[typeIndex(id) - 1]->Fill(ADC);
1127  }
1128  }
1129  }
1130 }
float getSignal(const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
bool gangedStrips() const
Definition: CSCGeometry.h:110
int typeIndex(CSCDetId id, int flag=1)
int station() const
Definition: CSCDetId.h:79
std::vector< MonitorElement * > hStripPed
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32

◆ doRecHits()

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 1138 of file CSCOfflineMonitor.cc.

References CSCDetId::endcap(), dqm::impl::MonitorElement::Fill(), hRHGlobal, hRHnrechits, hRHnrechitsHi, hRHRatioQ, hRHsterr, hRHstpos, hRHSumQ, hRHTiming, hRHTimingAnode, mps_fire::i, dqmiolumiharvest::j, CSCGeometry::layer(), FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::station(), GeomDet::toGlobal(), typeIndex(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by analyze().

1140  {
1141  // Get the RecHits collection :
1142  int nRecHits = recHits->size();
1143 
1144  // ---------------------
1145  // Loop over rechits
1146  // ---------------------
1147  // Build iterator for rechits and loop :
1149  for (dRHIter = recHits->begin(); dRHIter != recHits->end(); dRHIter++) {
1150  // Find chamber with rechits in CSC
1151  CSCDetId idrec = (CSCDetId)(*dRHIter).cscDetId();
1152 
1153  // Store rechit as a Local Point:
1154  LocalPoint rhitlocal = (*dRHIter).localPosition();
1155  //float xreco = rhitlocal.x();
1156  //float yreco = rhitlocal.y();
1157 
1158  // Get the reconstucted strip position and error
1159  float stpos = (*dRHIter).positionWithinStrip();
1160  float sterr = (*dRHIter).errorWithinStrip();
1161 
1163 
1164  int adcsize = dRHIter->nStrips() * dRHIter->nTimeBins();
1165  float rHSumQ = 0;
1166  float sumsides = 0;
1167  for (unsigned int i = 0; i < dRHIter->nStrips(); i++) {
1168  for (unsigned int j = 0; j < dRHIter->nTimeBins() - 1; j++) {
1169  rHSumQ += dRHIter->adcs(i, j);
1170  if (i != 1)
1171  sumsides += dRHIter->adcs(i, j); // skip central strip
1172  }
1173  }
1174 
1175  float rHratioQ = sumsides / rHSumQ;
1176  if (adcsize != 12)
1177  rHratioQ = -99;
1178 
1179  // Get the signal timing of this hit
1180  float rHtime = (*dRHIter).tpeak(); //calculated from cathode SCA bins
1181  float rHtimeAnode = (*dRHIter).wireTime(); // calculated from anode wire bx
1182 
1183  // Get pointer to the layer:
1184  const CSCLayer* csclayer = cscGeom->layer(idrec);
1185 
1186  // Transform hit position from local chamber geometry to global CMS geom
1187  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
1188  float grecx = rhitglobal.x();
1189  float grecy = rhitglobal.y();
1190 
1191  // Fill some histograms
1192  int sIndex = idrec.station() + ((idrec.endcap() - 1) * 4);
1193  int tIndex = typeIndex(idrec);
1194  hRHSumQ[tIndex - 1]->Fill(rHSumQ);
1195  hRHRatioQ[tIndex - 1]->Fill(rHratioQ);
1196  hRHstpos[tIndex - 1]->Fill(stpos);
1197  hRHsterr[tIndex - 1]->Fill(sterr);
1198  hRHTiming[tIndex - 1]->Fill(rHtime);
1199  hRHTimingAnode[tIndex - 1]->Fill(rHtimeAnode);
1200  hRHGlobal[sIndex - 1]->Fill(grecx, grecy);
1201 
1202  } //end rechit loop
1203 
1204  // if (nRecHits == 0) nRecHits = -1; // I see no point in doing this
1205  hRHnrechits->Fill(nRecHits);
1206  hRHnrechitsHi->Fill(nRecHits);
1207 }
std::vector< MonitorElement * > hRHSumQ
std::vector< MonitorElement * > hRHGlobal
void Fill(long long x)
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
std::vector< MonitorElement * > hRHstpos
int typeIndex(CSCDetId id, int flag=1)
MonitorElement * hRHnrechitsHi
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
int station() const
Definition: CSCDetId.h:79
std::vector< MonitorElement * > hRHTiming
int endcap() const
Definition: CSCDetId.h:85
std::vector< MonitorElement * > hRHTimingAnode
std::vector< MonitorElement * > hRHRatioQ
std::vector< MonitorElement * > hRHsterr
MonitorElement * hRHnrechits
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to given DetId.
Definition: CSCGeometry.cc:105

◆ doResolution()

void CSCOfflineMonitor::doResolution ( edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Find the strip containing this hit

Definition at line 1337 of file CSCOfflineMonitor.cc.

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

Referenced by analyze().

1338  {
1339  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1340  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1341  //
1342  // try to get the CSC recHits that contribute to this segment.
1343  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1344  int nRH = (*dSiter).nRecHits();
1345  int jRH = 0;
1346  CLHEP::HepMatrix sp(6, 1);
1347  CLHEP::HepMatrix se(6, 1);
1348  for (vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1349  jRH++;
1350  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
1351  //int kEndcap = idRH.endcap();
1352  int kRing = idRH.ring();
1353  int kStation = idRH.station();
1354  //int kChamber = idRH.chamber();
1355  int kLayer = idRH.layer();
1356 
1358  int centerid = iRH->nStrips() / 2 + 1;
1359  int centerStrip = iRH->channels(centerid - 1);
1360 
1361  // If this segment has 6 hits, find the position of each hit on the strip in units of stripwidth and store values
1362  if (nRH == 6) {
1363  float stpos = (*iRH).positionWithinStrip();
1364  se(kLayer, 1) = (*iRH).errorWithinStrip();
1365  // Take into account half-strip staggering of layers (ME1/1 has no staggering)
1366  if (kStation == 1 && (kRing == 1 || kRing == 4))
1367  sp(kLayer, 1) = stpos + centerStrip;
1368  else {
1369  if (kLayer == 1 || kLayer == 3 || kLayer == 5)
1370  sp(kLayer, 1) = stpos + centerStrip;
1371  if (kLayer == 2 || kLayer == 4 || kLayer == 6)
1372  sp(kLayer, 1) = stpos - 0.5 + centerStrip;
1373  }
1374  }
1375  }
1376 
1377  // Fit all points except layer 3, then compare expected value for layer 3 to reconstructed value
1378  // float residual = -99.; // used to fill always
1379  if (nRH == 6) {
1380  float expected = fitX(sp, se);
1381  float residual = expected - sp(3, 1);
1382 
1383  hSResid[typeIndex(id) - 1]->Fill(residual); // fill here so stats make sense
1384  }
1385 
1386  // hSResid[typeIndex(id)-1]->Fill(residual); // used to fill here but then stats distorted by underflows
1387 
1388  } // end segment loop
1389 }
std::vector< MonitorElement * > hSResid
int layer() const
Definition: CSCDetId.h:56
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
int typeIndex(CSCDetId id, int flag=1)
float fitX(const CLHEP::HepMatrix &sp, const CLHEP::HepMatrix &ep)
static const std::string kLayer("layer")
int station() const
Definition: CSCDetId.h:79
int ring() const
Definition: CSCDetId.h:68

◆ doSegments()

void CSCOfflineMonitor::doSegments ( edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Definition at line 1215 of file CSCOfflineMonitor.cc.

References CSCGeometry::chamber(), chamberSerial(), ChiSquaredProbability(), dtChamberEfficiency_cfi::cscSegments, dqm::impl::MonitorElement::Fill(), hSChiSq, hSChiSqAll, hSChiSqProb, hSChiSqProbAll, hSGlobalPhi, hSGlobalTheta, hSnhits, hSnhitsAll, hSnSegments, hSTimeAnode, hSTimeAnodeByChamberType, hSTimeAnodeSerial, hSTimeCathode, hSTimeCathodeByChamberType, hSTimeCathodeSerial, hSTimeCombined, hSTimeCombinedByChamberType, hSTimeCombinedSerial, hSTimeDiff, hSTimeDiffByChamberType, hSTimeDiffSerial, hSTimeVsTOF, hSTimeVsZ, mps_fire::i, dqmiolumiharvest::j, nhits, 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().

1215  {
1216  // get CSC segment collection
1217  int nSegments = cscSegments->size();
1218 
1219  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1220  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1221  float chisq = (*dSiter).chi2();
1222  int nhits = (*dSiter).nRecHits();
1223  int nDOF = 2 * nhits - 4;
1224  float nChi2 = chisq / nDOF;
1225  double chisqProb = ChiSquaredProbability((double)chisq, nDOF);
1226  LocalPoint localPos = (*dSiter).localPosition();
1227  LocalVector segDir = (*dSiter).localDirection();
1228 
1229  // prepare to calculate segment times
1230  float timeCathode = 0; //average from cathode information alone
1231  float timeAnode = 0; //average from pruned anode information alone
1232  float timeCombined = 0; //average from cathode hits and pruned anode list
1233  std::vector<float> cathodeTimes;
1234  std::vector<float> anodeTimes;
1235  // Get the CSC recHits that contribute to this segment.
1236  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1237  for (vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1238  if (!((*iRH).isValid()))
1239  continue; // only interested in valid hits
1240  cathodeTimes.push_back((*iRH).tpeak());
1241  anodeTimes.push_back((*iRH).wireTime());
1242  } //end rechit loop
1243 
1244  // Calculate cathode average
1245  for (unsigned int i = 0; i < cathodeTimes.size(); i++)
1246  timeCathode += cathodeTimes[i] / cathodeTimes.size();
1247 
1248  // Prune the anode list to deal with the late tail
1249  float anodeMaxDiff;
1250  bool modified = false;
1251  std::vector<float>::iterator anodeMaxHit;
1252  do {
1253  if (anodeTimes.empty())
1254  continue;
1255  timeAnode = 0;
1256  anodeMaxDiff = 0;
1257  modified = false;
1258 
1259  // Find the average
1260  for (unsigned int j = 0; j < anodeTimes.size(); j++)
1261  timeAnode += anodeTimes[j] / anodeTimes.size();
1262 
1263  // Find the maximum outlier hit
1264  for (unsigned int j = 0; j < anodeTimes.size(); j++) {
1265  if (fabs(anodeTimes[j] - timeAnode) > anodeMaxDiff) {
1266  anodeMaxHit = anodeTimes.begin() + j;
1267  anodeMaxDiff = fabs(anodeTimes[j] - timeAnode);
1268  }
1269  }
1270 
1271  // Cut hit if its greater than some time away
1272  if (anodeMaxDiff > 26) {
1273  modified = true;
1274  anodeTimes.erase(anodeMaxHit);
1275  }
1276  } while (modified);
1277 
1278  // Calculate combined anode and cathode time average
1279  if (cathodeTimes.size() + anodeTimes.size() > 0)
1280  timeCombined = (timeCathode * cathodeTimes.size() + timeAnode * anodeTimes.size()) /
1281  (cathodeTimes.size() + anodeTimes.size());
1282 
1283  // global transformation
1284  float globX = 0.;
1285  float globY = 0.;
1286  float globZ = 0.;
1287  float globTOF = 0.;
1288  float globTheta = 0.;
1289  float globPhi = 0.;
1290  const CSCChamber* cscchamber = cscGeom->chamber(id);
1291  if (cscchamber) {
1292  GlobalPoint globalPosition = cscchamber->toGlobal(localPos);
1293  globX = globalPosition.x();
1294  globY = globalPosition.y();
1295  globZ = globalPosition.z();
1296  globTOF = sqrt(globX * globX + globY * globY + globZ * globZ);
1297  GlobalVector globalDirection = cscchamber->toGlobal(segDir);
1298  globTheta = globalDirection.theta();
1299  globPhi = globalDirection.phi();
1300  }
1301 
1302  // Fill histos
1303  int tIndex = typeIndex(id);
1304  hSnhitsAll->Fill(nhits);
1305  hSnhits[tIndex - 1]->Fill(nhits);
1306  hSChiSqAll->Fill(nChi2);
1307  hSChiSq[tIndex - 1]->Fill(nChi2);
1308  hSChiSqProbAll->Fill(chisqProb);
1309  hSChiSqProb[tIndex - 1]->Fill(chisqProb);
1310  hSGlobalTheta->Fill(globTheta);
1311  hSGlobalPhi->Fill(globPhi);
1312  hSTimeDiff->Fill(timeAnode - timeCathode);
1313  hSTimeDiffByChamberType[tIndex - 1]->Fill(timeAnode - timeCathode);
1314  hSTimeAnode->Fill(timeAnode);
1315  hSTimeAnodeByChamberType[tIndex - 1]->Fill(timeAnode);
1316  hSTimeCathode->Fill(timeCathode);
1317  hSTimeCathodeByChamberType[tIndex - 1]->Fill(timeCathode);
1318  hSTimeCombined->Fill(timeCombined);
1319  hSTimeCombinedByChamberType[tIndex - 1]->Fill(timeCombined);
1320  hSTimeDiffSerial->Fill(chamberSerial(id), timeAnode - timeCathode);
1321  hSTimeAnodeSerial->Fill(chamberSerial(id), timeAnode);
1322  hSTimeCathodeSerial->Fill(chamberSerial(id), timeCathode);
1323  hSTimeCombinedSerial->Fill(chamberSerial(id), timeCombined);
1324  hSTimeVsZ->Fill(globZ, timeCombined);
1325  hSTimeVsTOF->Fill(globTOF, timeCombined);
1326 
1327  } // end segment loop
1328 
1329  hSnSegments->Fill(nSegments);
1330 }
std::vector< MonitorElement * > hSTimeCathodeByChamberType
int chamberSerial(CSCDetId id)
std::vector< MonitorElement * > hSTimeAnodeByChamberType
std::vector< MonitorElement * > hSTimeDiffByChamberType
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:100
T z() const
Definition: PV3DBase.h:61
Geom::Phi< T > phi() const
Definition: PV3DBase.h:66
MonitorElement * hSTimeAnodeSerial
MonitorElement * hSTimeAnode
MonitorElement * hSGlobalPhi
std::vector< MonitorElement * > hSnhits
void Fill(long long x)
MonitorElement * hSnSegments
C::const_iterator const_iterator
constant access iterator type
Definition: RangeMap.h:43
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
int typeIndex(CSCDetId id, int flag=1)
MonitorElement * hSnhitsAll
T sqrt(T t)
Definition: SSEVec.h:19
std::vector< MonitorElement * > hSChiSq
MonitorElement * hSGlobalTheta
MonitorElement * hSTimeDiffSerial
float ChiSquaredProbability(double chiSquared, double nrDOF)
MonitorElement * hSTimeCombined
std::vector< MonitorElement * > hSTimeCombinedByChamberType
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
MonitorElement * hSTimeVsZ
MonitorElement * hSChiSqAll
MonitorElement * hSTimeDiff
MonitorElement * hSTimeCathode
std::vector< MonitorElement * > hSChiSqProb
MonitorElement * hSTimeCathodeSerial
MonitorElement * hSTimeCombinedSerial
MonitorElement * hSTimeVsTOF
MonitorElement * hSChiSqProbAll
Geom::Theta< T > theta() const
Definition: PV3DBase.h:72

◆ doStripDigis()

void CSCOfflineMonitor::doStripDigis ( edm::Handle< CSCStripDigiCollection strips)
private

Definition at line 1057 of file CSCOfflineMonitor.cc.

References change_name::diff, dqm::impl::MonitorElement::Fill(), dqmMemoryStats::float, cms::cuda::for(), hStripNFired, hStripNFiredHi, hStripNumber, DigiDM_cff::strips, remoteMonitoring_LASER_era2018_cfg::threshold, and typeIndex().

Referenced by analyze().

1057  {
1058  int nStripsFired = 0;
1059  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
1060  CSCDetId id = (CSCDetId)(*dSDiter).first;
1061  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
1062  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
1063  for (; stripIter != lStrip; ++stripIter) {
1064  int myStrip = stripIter->getStrip();
1065  std::vector<int> myADCVals = stripIter->getADCCounts();
1066  bool thisStripFired = false;
1067  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1068  float threshold = 13.3;
1069  float diff = 0.;
1070  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
1071  diff = (float)myADCVals[iCount] - thisPedestal;
1072  if (diff > threshold) {
1073  thisStripFired = true;
1074  }
1075  }
1076  if (thisStripFired) {
1077  nStripsFired++;
1078  hStripNumber[typeIndex(id) - 1]->Fill(myStrip);
1079  }
1080  }
1081  } // end strip loop
1082 
1083  hStripNFired->Fill(nStripsFired);
1084  hStripNFiredHi->Fill(nStripsFired);
1085 
1086  // fill n per event
1087 }
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
std::vector< MonitorElement * > hStripNumber
void Fill(long long x)
int typeIndex(CSCDetId id, int flag=1)
MonitorElement * hStripNFired
strips
#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers.hcal.doNoise = False simEcalUnsuppressedDigis.doNoise = False mix.digitizers.ecal.doNoise = False simEcalUnsuppressedDigis.doESNoise = False simSiPixelDigis.AddNoise = False mix.digitizers.pixel.AddNoise = False simSiStripDigis.Noise = False mix.digitizers.strip.AddNoise = False
Definition: DigiDM_cff.py:32
MonitorElement * hStripNFiredHi

◆ doWireDigis()

void CSCOfflineMonitor::doWireDigis ( edm::Handle< CSCWireDigiCollection wires)
private

Definition at line 1032 of file CSCOfflineMonitor.cc.

References dqm::impl::MonitorElement::Fill(), cms::cuda::for(), hWirenGroupsTotal, hWirenGroupsTotalHi, hWireNumber, hWireTBin, typeIndex(), and DigiDM_cff::wires.

Referenced by analyze().

1032  {
1033  int nWireGroupsTotal = 0;
1034  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
1035  CSCDetId id = (CSCDetId)(*dWDiter).first;
1036  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
1037  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
1038  for (; wireIter != lWire; ++wireIter) {
1039  int myWire = wireIter->getWireGroup();
1040  int myTBin = wireIter->getTimeBin();
1041  nWireGroupsTotal++;
1042  hWireTBin[typeIndex(id) - 1]->Fill(myTBin);
1043  hWireNumber[typeIndex(id) - 1]->Fill(myWire);
1044  }
1045  } // end wire loop
1046 
1047  hWirenGroupsTotal->Fill(nWireGroupsTotal);
1048  hWirenGroupsTotalHi->Fill(nWireGroupsTotal);
1049 }
std::vector< MonitorElement * > hWireNumber
for(int i=first, nt=offsets[nh];i< nt;i+=gridDim.x *blockDim.x)
MonitorElement * hWirenGroupsTotal
void Fill(long long x)
int typeIndex(CSCDetId id, int flag=1)
std::vector< MonitorElement * > hWireTBin
MonitorElement * hWirenGroupsTotalHi

◆ extrapolate1D()

double CSCOfflineMonitor::extrapolate1D ( double  initPosition,
double  initDirection,
double  parameterOfTheLine 
)
inlineprivate

Definition at line 141 of file CSCOfflineMonitor.h.

Referenced by doEfficiencies().

141  {
142  double extrapolatedPosition = initPosition + initDirection * parameterOfTheLine;
143  return extrapolatedPosition;
144  }

◆ fillEfficiencyHistos()

void CSCOfflineMonitor::fillEfficiencyHistos ( int  bin,
int  flag 
)
private

◆ fitX()

float CSCOfflineMonitor::fitX ( const CLHEP::HepMatrix &  sp,
const CLHEP::HepMatrix &  ep 
)
private

Definition at line 1396 of file CSCOfflineMonitor.cc.

References dumpMFGeometry_cfg::delta, debug_messages_cfi::errors, mps_fire::i, hiPixelPairStep_cff::points, and slope.

Referenced by doResolution().

1396  {
1397  float S = 0;
1398  float Sx = 0;
1399  float Sy = 0;
1400  float Sxx = 0;
1401  float Sxy = 0;
1402  float sigma2 = 0;
1403 
1404  for (int i = 1; i < 7; i++) {
1405  if (i != 3) {
1406  sigma2 = errors(i, 1) * errors(i, 1);
1407  S = S + (1 / sigma2);
1408  Sy = Sy + (points(i, 1) / sigma2);
1409  Sx = Sx + ((i) / sigma2);
1410  Sxx = Sxx + (i * i) / sigma2;
1411  Sxy = Sxy + (((i)*points(i, 1)) / sigma2);
1412  }
1413  }
1414 
1415  float delta = S * Sxx - Sx * Sx;
1416  float intercept = (Sxx * Sy - Sx * Sxy) / delta;
1417  float slope = (S * Sxy - Sx * Sy) / delta;
1418 
1419  return (intercept + slope * 3);
1420 }
static const double slope[3]

◆ getSignal()

float CSCOfflineMonitor::getSignal ( const CSCStripDigiCollection stripdigis,
CSCDetId  idRH,
int  centerStrip 
)
private

Definition at line 1429 of file CSCOfflineMonitor.cc.

References dqmMemoryStats::float, if(), and dqmdumpme::last.

Referenced by doPedestalNoise().

1429  {
1430  float SigADC[5];
1431  float TotalADC = 0;
1432  SigADC[0] = 0;
1433  SigADC[1] = 0;
1434  SigADC[2] = 0;
1435  SigADC[3] = 0;
1436  SigADC[4] = 0;
1437 
1438  // Loop over strip digis
1440 
1441  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
1442  CSCDetId id = (CSCDetId)(*sIt).first;
1443  if (id == idCS) {
1444  // First, find the Signal-Pedestal for center strip
1445  vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
1446  vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
1447  for (; digiItr != last; ++digiItr) {
1448  int thisStrip = digiItr->getStrip();
1449  if (thisStrip == (centerStrip)) {
1450  std::vector<int> myADCVals = digiItr->getADCCounts();
1451  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1452  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1453  SigADC[0] = thisSignal - 6 * thisPedestal;
1454  }
1455  // Now,find the Signal-Pedestal for neighbouring 4 strips
1456  if (thisStrip == (centerStrip + 1)) {
1457  std::vector<int> myADCVals = digiItr->getADCCounts();
1458  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1459  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1460  SigADC[1] = thisSignal - 6 * thisPedestal;
1461  }
1462  if (thisStrip == (centerStrip + 2)) {
1463  std::vector<int> myADCVals = digiItr->getADCCounts();
1464  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1465  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1466  SigADC[2] = thisSignal - 6 * thisPedestal;
1467  }
1468  if (thisStrip == (centerStrip - 1)) {
1469  std::vector<int> myADCVals = digiItr->getADCCounts();
1470  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1471  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1472  SigADC[3] = thisSignal - 6 * thisPedestal;
1473  }
1474  if (thisStrip == (centerStrip - 2)) {
1475  std::vector<int> myADCVals = digiItr->getADCCounts();
1476  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1477  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1478  SigADC[4] = thisSignal - 6 * thisPedestal;
1479  }
1480  }
1481  TotalADC = 0.2 * (SigADC[0] + SigADC[1] + SigADC[2] + SigADC[3] + SigADC[4]);
1482  }
1483  }
1484  return TotalADC;
1485 }

◆ lineParametrization()

double CSCOfflineMonitor::lineParametrization ( double  z1Position,
double  z2Position,
double  z1Direction 
)
inlineprivate

Definition at line 136 of file CSCOfflineMonitor.h.

Referenced by doEfficiencies().

136  {
137  double parameterLine = (z2Position - z1Position) / z1Direction;
138  return parameterLine;
139  }

◆ typeIndex()

int CSCOfflineMonitor::typeIndex ( CSCDetId  id,
int  flag = 1 
)
private

Definition at line 2083 of file CSCOfflineMonitor.cc.

References makeMuonMisalignmentScenario::endcap, RemoveAddSevLevel::flag, relativeConstraints::ring, and relativeConstraints::station.

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

2083  {
2084  // linearized index based on endcap, station, and ring
2085 
2086  if (flag == 1) {
2087  int index = 0;
2088  if (id.station() == 1)
2089  index = id.ring();
2090  else
2091  index = id.station() * 2 + id.ring();
2092  if (id.endcap() == 1)
2093  index = index + 10;
2094  if (id.endcap() == 2)
2095  index = 11 - index;
2096  return index;
2097  }
2098 
2099  else if (flag == 2) {
2100  int index = 0;
2101  if (id.station() == 1 && id.ring() != 4)
2102  index = id.ring() + 1;
2103  if (id.station() == 1 && id.ring() == 4)
2104  index = 1;
2105  if (id.station() != 1)
2106  index = id.station() * 2 + id.ring();
2107  if (id.endcap() == 1)
2108  index = index + 10;
2109  if (id.endcap() == 2)
2110  index = 11 - index;
2111  return index;
2112  }
2113 
2114  else
2115  return 0;
2116 }

◆ withinSensitiveRegion()

bool CSCOfflineMonitor::withinSensitiveRegion ( LocalPoint  localPos,
const std::array< const float, 4 > &  layerBounds,
int  station,
int  ring,
float  shiftFromEdge,
float  shiftFromDeadZone 
)
private

Definition at line 1985 of file CSCOfflineMonitor.cc.

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

Referenced by doEfficiencies().

1990  {
1991  //---- check if it is in a good local region (sensitive area - geometrical and HV boundaries excluded)
1992  bool pass = false;
1993 
1994  float y_center = 0.;
1995  double yUp = layerBounds[3] + y_center;
1996  double yDown = -layerBounds[3] + y_center;
1997  double xBound1Shifted = layerBounds[0] - shiftFromEdge; //
1998  double xBound2Shifted = layerBounds[1] - shiftFromEdge; //
1999  double lineSlope = (yUp - yDown) / (xBound2Shifted - xBound1Shifted);
2000  double lineConst = yUp - lineSlope * xBound2Shifted;
2001  double yBorder = lineSlope * abs(localPos.x()) + lineConst;
2002 
2003  //bool withinChamberOnly = false;// false = "good region"; true - boundaries only
2004  std::vector<float> deadZoneCenter(6);
2005  float cutZone = shiftFromDeadZone; //cm
2006  //---- hardcoded... not good
2007  if (station > 1 && station < 5) {
2008  if (2 == ring) {
2009  deadZoneCenter[0] = -162.48;
2010  deadZoneCenter[1] = -81.8744;
2011  deadZoneCenter[2] = -21.18165;
2012  deadZoneCenter[3] = 39.51105;
2013  deadZoneCenter[4] = 100.2939;
2014  deadZoneCenter[5] = 160.58;
2015 
2016  if (localPos.y() > yBorder &&
2017  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
2018  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
2019  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone) ||
2020  (localPos.y() > deadZoneCenter[3] + cutZone && localPos.y() < deadZoneCenter[4] - cutZone) ||
2021  (localPos.y() > deadZoneCenter[4] + cutZone && localPos.y() < deadZoneCenter[5] - cutZone))) {
2022  pass = true;
2023  }
2024  } else if (1 == ring) {
2025  if (2 == station) {
2026  deadZoneCenter[0] = -95.80;
2027  deadZoneCenter[1] = -27.47;
2028  deadZoneCenter[2] = 33.67;
2029  deadZoneCenter[3] = 90.85;
2030  } else if (3 == station) {
2031  deadZoneCenter[0] = -89.305;
2032  deadZoneCenter[1] = -39.705;
2033  deadZoneCenter[2] = 20.195;
2034  deadZoneCenter[3] = 77.395;
2035  } else if (4 == station) {
2036  deadZoneCenter[0] = -75.645;
2037  deadZoneCenter[1] = -26.055;
2038  deadZoneCenter[2] = 23.855;
2039  deadZoneCenter[3] = 70.575;
2040  }
2041  if (localPos.y() > yBorder &&
2042  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
2043  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
2044  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
2045  pass = true;
2046  }
2047  }
2048  } else if (1 == station) {
2049  if (3 == ring) {
2050  deadZoneCenter[0] = -83.155;
2051  deadZoneCenter[1] = -22.7401;
2052  deadZoneCenter[2] = 27.86665;
2053  deadZoneCenter[3] = 81.005;
2054  if (localPos.y() > yBorder &&
2055  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
2056  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
2057  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
2058  pass = true;
2059  }
2060  } else if (2 == ring) {
2061  deadZoneCenter[0] = -86.285;
2062  deadZoneCenter[1] = -32.88305;
2063  deadZoneCenter[2] = 32.867423;
2064  deadZoneCenter[3] = 88.205;
2065  if (localPos.y() > (yBorder) &&
2066  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
2067  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
2068  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
2069  pass = true;
2070  }
2071  } else {
2072  deadZoneCenter[0] = -81.0;
2073  deadZoneCenter[1] = 81.0;
2074  if (localPos.y() > (yBorder) &&
2075  (localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone)) {
2076  pass = true;
2077  }
2078  }
2079  }
2080  return pass;
2081 }
T x() const
Definition: PV3DBase.h:59
T y() const
Definition: PV3DBase.h:60
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

Member Data Documentation

◆ al_token

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

Definition at line 89 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

◆ cl_token

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

Definition at line 90 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

◆ cscGeomToken_

const edm::ESGetToken<CSCGeometry, MuonGeometryRecord> CSCOfflineMonitor::cscGeomToken_
private

Definition at line 94 of file CSCOfflineMonitor.h.

Referenced by analyze().

◆ hALCTgetBX

MonitorElement* CSCOfflineMonitor::hALCTgetBX
private

Definition at line 241 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTgetBX2Denominator

MonitorElement* CSCOfflineMonitor::hALCTgetBX2Denominator
private

Definition at line 245 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTgetBX2DNumerator

MonitorElement* CSCOfflineMonitor::hALCTgetBX2DNumerator
private

Definition at line 246 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTgetBXSerial

MonitorElement* CSCOfflineMonitor::hALCTgetBXSerial
private

Definition at line 242 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTMatch

MonitorElement* CSCOfflineMonitor::hALCTMatch
private

Definition at line 248 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTMatch2Denominator

MonitorElement* CSCOfflineMonitor::hALCTMatch2Denominator
private

Definition at line 252 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTMatch2DNumerator

MonitorElement* CSCOfflineMonitor::hALCTMatch2DNumerator
private

Definition at line 253 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hALCTMatchSerial

MonitorElement* CSCOfflineMonitor::hALCTMatchSerial
private

Definition at line 249 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hCLCTL1A

MonitorElement* CSCOfflineMonitor::hCLCTL1A
private

Definition at line 255 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hCLCTL1A2Denominator

MonitorElement* CSCOfflineMonitor::hCLCTL1A2Denominator
private

Definition at line 259 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hCLCTL1A2DNumerator

MonitorElement* CSCOfflineMonitor::hCLCTL1A2DNumerator
private

Definition at line 260 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hCLCTL1ASerial

MonitorElement* CSCOfflineMonitor::hCLCTL1ASerial
private

Definition at line 256 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doBXMonitor().

◆ hcrateToken_

const edm::ESGetToken<CSCCrateMap, CSCCrateMapRcd> CSCOfflineMonitor::hcrateToken_
private

Definition at line 96 of file CSCOfflineMonitor.h.

Referenced by doBXMonitor().

◆ hCSCOccupancy

MonitorElement* CSCOfflineMonitor::hCSCOccupancy
private

Definition at line 219 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hEffDenominator

MonitorElement* CSCOfflineMonitor::hEffDenominator
private

Definition at line 237 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hORecHits

MonitorElement* CSCOfflineMonitor::hORecHits
private

Definition at line 213 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hORecHitsSerial

MonitorElement* CSCOfflineMonitor::hORecHitsSerial
private

Definition at line 217 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOSegments

MonitorElement* CSCOfflineMonitor::hOSegments
private

Definition at line 214 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOSegmentsSerial

MonitorElement* CSCOfflineMonitor::hOSegmentsSerial
private

Definition at line 218 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOStrips

MonitorElement* CSCOfflineMonitor::hOStrips
private

Definition at line 211 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOStripsAndWiresAndCLCT

MonitorElement* CSCOfflineMonitor::hOStripsAndWiresAndCLCT
private

Definition at line 212 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOStripSerial

MonitorElement* CSCOfflineMonitor::hOStripSerial
private

Definition at line 216 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOWires

MonitorElement* CSCOfflineMonitor::hOWires
private

Definition at line 209 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOWiresAndCLCT

MonitorElement* CSCOfflineMonitor::hOWiresAndCLCT
private

Definition at line 210 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hOWireSerial

MonitorElement* CSCOfflineMonitor::hOWireSerial
private

Definition at line 215 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doOccupancies().

◆ hRHden

MonitorElement* CSCOfflineMonitor::hRHden
private

Definition at line 225 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hRHGlobal

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

Definition at line 172 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHnrechits

MonitorElement* CSCOfflineMonitor::hRHnrechits
private

Definition at line 170 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHnrechitsHi

MonitorElement* CSCOfflineMonitor::hRHnrechitsHi
private

Definition at line 171 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHnum

MonitorElement* CSCOfflineMonitor::hRHnum
private

Definition at line 224 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hRHRatioQ

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

Definition at line 176 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHSTE2

MonitorElement* CSCOfflineMonitor::hRHSTE2
private

Definition at line 229 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hRHsterr

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

Definition at line 178 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHstpos

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

Definition at line 177 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHSumQ

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

Definition at line 173 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHTiming

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

Definition at line 174 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hRHTimingAnode

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

Definition at line 175 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doRecHits().

◆ hSChiSq

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

Definition at line 185 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSChiSqAll

MonitorElement* CSCOfflineMonitor::hSChiSqAll
private

Definition at line 184 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSChiSqProb

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

Definition at line 187 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSChiSqProbAll

MonitorElement* CSCOfflineMonitor::hSChiSqProbAll
private

Definition at line 186 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSden

MonitorElement* CSCOfflineMonitor::hSden
private

Definition at line 223 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hSensitiveAreaEvt

MonitorElement* CSCOfflineMonitor::hSensitiveAreaEvt
private

Definition at line 238 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hSGlobalPhi

MonitorElement* CSCOfflineMonitor::hSGlobalPhi
private

Definition at line 189 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSGlobalTheta

MonitorElement* CSCOfflineMonitor::hSGlobalTheta
private

Definition at line 188 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSnhits

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

Definition at line 183 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSnhitsAll

MonitorElement* CSCOfflineMonitor::hSnhitsAll
private

Definition at line 182 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSnSegments

MonitorElement* CSCOfflineMonitor::hSnSegments
private

Definition at line 181 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSnum

MonitorElement* CSCOfflineMonitor::hSnum
private

Definition at line 222 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hSResid

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

Definition at line 206 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doResolution().

◆ hSSTE2

MonitorElement* CSCOfflineMonitor::hSSTE2
private

Definition at line 228 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hSTimeAnode

MonitorElement* CSCOfflineMonitor::hSTimeAnode
private

Definition at line 192 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeAnodeByChamberType

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

Definition at line 193 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeAnodeSerial

MonitorElement* CSCOfflineMonitor::hSTimeAnodeSerial
private

Definition at line 199 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCathode

MonitorElement* CSCOfflineMonitor::hSTimeCathode
private

Definition at line 194 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCathodeByChamberType

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

Definition at line 195 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCathodeSerial

MonitorElement* CSCOfflineMonitor::hSTimeCathodeSerial
private

Definition at line 200 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCombined

MonitorElement* CSCOfflineMonitor::hSTimeCombined
private

Definition at line 196 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCombinedByChamberType

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

Definition at line 197 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeCombinedSerial

MonitorElement* CSCOfflineMonitor::hSTimeCombinedSerial
private

Definition at line 201 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeDiff

MonitorElement* CSCOfflineMonitor::hSTimeDiff
private

Definition at line 190 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeDiffByChamberType

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

Definition at line 191 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeDiffSerial

MonitorElement* CSCOfflineMonitor::hSTimeDiffSerial
private

Definition at line 198 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeVsTOF

MonitorElement* CSCOfflineMonitor::hSTimeVsTOF
private

Definition at line 203 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hSTimeVsZ

MonitorElement* CSCOfflineMonitor::hSTimeVsZ
private

Definition at line 202 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doSegments().

◆ hStripNFired

MonitorElement* CSCOfflineMonitor::hStripNFired
private

Definition at line 164 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doStripDigis().

◆ hStripNFiredHi

MonitorElement* CSCOfflineMonitor::hStripNFiredHi
private

Definition at line 165 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doStripDigis().

◆ hStripNumber

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

Definition at line 166 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doStripDigis().

◆ hStripPed

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

Definition at line 167 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doPedestalNoise().

◆ hStripSTE2

MonitorElement* CSCOfflineMonitor::hStripSTE2
private

Definition at line 230 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hWirenGroupsTotal

MonitorElement* CSCOfflineMonitor::hWirenGroupsTotal
private

Definition at line 158 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doWireDigis().

◆ hWirenGroupsTotalHi

MonitorElement* CSCOfflineMonitor::hWirenGroupsTotalHi
private

Definition at line 159 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doWireDigis().

◆ hWireNumber

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

Definition at line 161 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doWireDigis().

◆ hWireSTE2

MonitorElement* CSCOfflineMonitor::hWireSTE2
private

Definition at line 231 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doEfficiencies().

◆ hWireTBin

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

Definition at line 160 of file CSCOfflineMonitor.h.

Referenced by bookHistograms(), and doWireDigis().

◆ param

edm::ParameterSet CSCOfflineMonitor::param
private

Definition at line 84 of file CSCOfflineMonitor.h.

◆ rd_token

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

Definition at line 86 of file CSCOfflineMonitor.h.

Referenced by CSCOfflineMonitor(), and doBXMonitor().

◆ rh_token

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

Definition at line 91 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

◆ sd_token

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

Definition at line 88 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

◆ se_token

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

Definition at line 92 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().

◆ wd_token

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

Definition at line 87 of file CSCOfflineMonitor.h.

Referenced by analyze(), and CSCOfflineMonitor().