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CSCValidation Class Reference

#include <CSCValidation.h>

Inheritance diagram for CSCValidation:
edm::EDAnalyzer edm::EDConsumerBase

Classes

struct  ltrh
 

Public Member Functions

void analyze (const edm::Event &event, const edm::EventSetup &eventSetup) override
 Perform the analysis. More...
 
 CSCValidation (const edm::ParameterSet &pset)
 Constructor. More...
 
void endJob () override
 
 ~CSCValidation () override
 Destructor. More...
 
- Public Member Functions inherited from edm::EDAnalyzer
void callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
 
 EDAnalyzer ()
 
SerialTaskQueueglobalLuminosityBlocksQueue ()
 
SerialTaskQueueglobalRunsQueue ()
 
ModuleDescription const & moduleDescription () const
 
std::string workerType () const
 
 ~EDAnalyzer () override
 
- Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfoconsumesInfo () const
 
void convertCurrentProcessAlias (std::string const &processName)
 Convert "@currentProcess" in InputTag process names to the actual current process name. More...
 
 EDConsumerBase ()
 
 EDConsumerBase (EDConsumerBase &&)=default
 
 EDConsumerBase (EDConsumerBase const &)=delete
 
ESProxyIndex const * esGetTokenIndices (edm::Transition iTrans) const
 
std::vector< ESProxyIndex > const & esGetTokenIndicesVector (edm::Transition iTrans) const
 
std::vector< ESRecordIndex > const & esGetTokenRecordIndicesVector (edm::Transition iTrans) const
 
ProductResolverIndexAndSkipBit indexFrom (EDGetToken, BranchType, TypeID const &) const
 
void itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
 
void itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
 
std::vector< ProductResolverIndexAndSkipBit > const & itemsToGetFrom (BranchType iType) const
 
void labelsForToken (EDGetToken iToken, Labels &oLabels) const
 
void modulesWhoseProductsAreConsumed (std::array< std::vector< ModuleDescription const * > *, NumBranchTypes > &modulesAll, std::vector< ModuleProcessName > &modulesInPreviousProcesses, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
 
EDConsumerBaseoperator= (EDConsumerBase &&)=default
 
EDConsumerBase const & operator= (EDConsumerBase const &)=delete
 
bool registeredToConsume (ProductResolverIndex, bool, BranchType) const
 
bool registeredToConsumeMany (TypeID const &, BranchType) const
 
ProductResolverIndexAndSkipBit uncheckedIndexFrom (EDGetToken) const
 
void updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
 
void updateLookup (eventsetup::ESRecordsToProxyIndices const &)
 
virtual ~EDConsumerBase () noexcept(false)
 

Private Member Functions

int chamberSerial (CSCDetId id)
 
void doADCTiming (const CSCRecHit2DCollection &)
 
void doAFEBTiming (const CSCWireDigiCollection &)
 
void doCalibrations (const edm::EventSetup &eventSetup)
 
void doCompTiming (const CSCComparatorDigiCollection &)
 
void doEfficiencies (edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
 
void doGasGain (const CSCWireDigiCollection &, const CSCStripDigiCollection &, const CSCRecHit2DCollection &)
 
bool doHLT (edm::Handle< edm::TriggerResults > hltResults)
 
void doNoiseHits (edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom, edm::Handle< CSCStripDigiCollection > strips)
 
void doOccupancies (edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments)
 
void doPedestalNoise (edm::Handle< CSCStripDigiCollection > strips)
 
void doRecHits (edm::Handle< CSCRecHit2DCollection > recHits, 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 doSimHits (edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< edm::PSimHitContainer > simHits)
 
void doStandalone (edm::Handle< reco::TrackCollection > saMuons)
 
void doStripDigis (edm::Handle< CSCStripDigiCollection > strips)
 
void doTimeMonitoring (edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::Handle< CSCALCTDigiCollection > alcts, edm::Handle< CSCCLCTDigiCollection > clcts, edm::Handle< CSCCorrelatedLCTDigiCollection > correlatedlcts, edm::Handle< L1MuGMTReadoutCollection > pCollection, edm::ESHandle< CSCGeometry > cscGeom, const edm::EventSetup &eventSetup, const edm::Event &event)
 
bool doTrigger (edm::Handle< L1MuGMTReadoutCollection > pCollection)
 
void doWireDigis (edm::Handle< CSCWireDigiCollection > wires)
 
double extrapolate1D (double initPosition, double initDirection, double parameterOfTheLine)
 
void fillEfficiencyHistos (int bin, int flag)
 
bool filterEvents (edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::Handle< reco::TrackCollection > saMuons)
 
void findNonAssociatedRecHits (edm::ESHandle< CSCGeometry > cscGeom, edm::Handle< CSCStripDigiCollection > strips)
 
float fitX (const CLHEP::HepMatrix &sp, const CLHEP::HepMatrix &ep)
 
void getEfficiency (float bin, float Norm, std::vector< float > &eff)
 
float getSignal (const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
 
float getthisSignal (const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
 
int getWidth (const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
 
void histoEfficiency (TH1F *readHisto, TH1F *writeHisto)
 
double lineParametrization (double z1Position, double z2Position, double z1Direction)
 
int ringSerial (CSCDetId id)
 
int typeIndex (CSCDetId id)
 
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
 
std::multimap< CSCDetId, CSCRecHit2DAllRechits
 
edm::EDGetTokenT< CSCComparatorDigiCollectioncd_token
 
double chisqMax
 
edm::EDGetTokenT< CSCCLCTDigiCollectioncl_token
 
bool cleanEvent
 
edm::EDGetTokenT< CSCCorrelatedLCTDigiCollectionco_token
 
double deltaPhiMax
 
bool detailedAnalysis
 
std::map< CSCRecHit2D, float, ltrhdistRHmap
 
bool firstEvent
 
edm::ESGetToken< CSCGeometry, MuonGeometryRecordgeomToken_
 
TH2F * hEffDenominator
 
CSCValHistshistos
 
TH2I * hORecHits
 
TH2I * hOSegments
 
TH2I * hOStrips
 
TH2I * hOWires
 
TH1F * hRHEff
 
TH2F * hRHEff2
 
TH1F * hRHSTE
 
TH2F * hRHSTE2
 
TH1F * hSEff
 
TH2F * hSEff2
 
TH2F * hSensitiveAreaEvt
 
TH1F * hSSTE
 
TH2F * hSSTE2
 
TH2F * hStripEff2
 
TH2F * hStripSTE2
 
TH2F * hWireEff2
 
TH2F * hWireSTE2
 
bool isSimulation
 
edm::EDGetTokenT< L1MuGMTReadoutCollectionl1_token
 
double lengthMax
 
double lengthMin
 
std::map< int, int > m_single_wire_layer
 
std::map< int, std::vector< int > > m_wire_hvsegm
 
bool makeADCTimingPlots
 
bool makeAFEBTimingPlots
 
bool makeCalibPlots
 
bool makeComparisonPlots
 
bool makeCompTimingPlots
 
bool makeEfficiencyPlots
 
bool makeGasGainPlots
 
bool makeHLTPlots
 
bool makeOccupancyPlots
 
bool makePedNoisePlots
 
bool makePlots
 
bool makeRecHitPlots
 
bool makeResolutionPlots
 
bool makeRHNoisePlots
 
bool makeSegmentPlots
 
bool makeSimHitPlots
 
bool makeStandalonePlots
 
bool makeStripPlots
 
bool makeTimeMonitorPlots
 
bool makeTriggerPlots
 
bool makeWirePlots
 
int nCSCHitsMax
 
int nCSCHitsMin
 
int nEventsAnalyzed
 
std::vector< int > nmbhvsegm
 Maps and vectors for module doGasGain() More...
 
std::multimap< CSCDetId, CSCRecHit2DNonAssociatedRechits
 
double pMin
 
double polarMax
 
double polarMin
 
edm::EDGetTokenT< FEDRawDataCollectionrd_token
 
std::string refRootFile
 
edm::EDGetTokenT< CSCRecHit2DCollectionrh_token
 
int rhTreeCount
 
std::string rootFileName
 
edm::EDGetTokenT< reco::TrackCollectionsa_token
 
edm::EDGetTokenT< CSCStripDigiCollectionsd_token
 
edm::EDGetTokenT< CSCSegmentCollectionse_token
 
std::multimap< CSCDetId, CSCRecHit2DSegRechits
 
int segTreeCount
 
edm::EDGetTokenT< edm::PSimHitContainersh_token
 
TFile * theFile
 
edm::EDGetTokenT< edm::TriggerResultstr_token
 
bool useDigis
 
bool useQualityFilter
 
bool useTriggerFilter
 
edm::EDGetTokenT< CSCWireDigiCollectionwd_token
 
bool writeTreeToFile
 

Additional Inherited Members

- Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer ModuleType
 
- Public Types inherited from edm::EDConsumerBase
typedef ProductLabels Labels
 
- Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string & baseType ()
 
static void fillDescriptions (ConfigurationDescriptions &descriptions)
 
static void prevalidate (ConfigurationDescriptions &)
 
static bool wantsGlobalLuminosityBlocks ()
 
static bool wantsGlobalRuns ()
 
static bool wantsInputProcessBlocks ()
 
static bool wantsProcessBlocks ()
 
static bool wantsStreamLuminosityBlocks ()
 
static bool wantsStreamRuns ()
 
- Protected Member Functions inherited from edm::EDConsumerBase
EDGetToken consumes (const TypeToGet &id, edm::InputTag const &tag)
 
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType > consumes (edm::InputTag const &tag)
 
template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B > consumes (edm::InputTag tag) noexcept
 
template<BranchType B>
EDGetToken consumes (TypeToGet const &id, edm::InputTag const &tag)
 
ConsumesCollector consumesCollector ()
 Use a ConsumesCollector to gather consumes information from helper functions. More...
 
template<typename ProductType , BranchType B = InEvent>
void consumesMany ()
 
void consumesMany (const TypeToGet &id)
 
template<BranchType B>
void consumesMany (const TypeToGet &id)
 
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto esConsumes ()
 
template<Transition Tr = Transition::Event>
constexpr auto esConsumes () noexcept
 
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto esConsumes (ESInputTag const &tag)
 
template<Transition Tr = Transition::Event>
auto esConsumes (ESInputTag tag) noexcept
 
template<Transition Tr = Transition::Event>
ESGetTokenGeneric esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
 Used with EventSetupRecord::doGet. More...
 
EDGetToken mayConsume (const TypeToGet &id, edm::InputTag const &tag)
 
template<BranchType B>
EDGetToken mayConsume (const TypeToGet &id, edm::InputTag const &tag)
 
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType > mayConsume (edm::InputTag const &tag)
 

Detailed Description

Package to validate local CSC reconstruction: DIGIS recHits segments L1 trigger CSC STA muons Various efficiencies

Responsible: Andy Kubik, Northwestern University

Definition at line 105 of file CSCValidation.h.

Constructor & Destructor Documentation

◆ CSCValidation()

CSCValidation::CSCValidation ( const edm::ParameterSet pset)

Constructor.

Definition at line 16 of file CSCValidation.cc.

16  {
17  // Get the various input parameters
18  rootFileName = pset.getUntrackedParameter<std::string>("rootFileName", "valHists.root");
19  isSimulation = pset.getUntrackedParameter<bool>("isSimulation", false);
20  writeTreeToFile = pset.getUntrackedParameter<bool>("writeTreeToFile", true);
21  detailedAnalysis = pset.getUntrackedParameter<bool>("detailedAnalysis", false);
22  useDigis = pset.getUntrackedParameter<bool>("useDigis", true);
23 
24  // event quality filter
25  useQualityFilter = pset.getUntrackedParameter<bool>("useQualityFilter", false);
26  pMin = pset.getUntrackedParameter<double>("pMin", 4.);
27  chisqMax = pset.getUntrackedParameter<double>("chisqMax", 20.);
28  nCSCHitsMin = pset.getUntrackedParameter<int>("nCSCHitsMin", 10);
29  nCSCHitsMax = pset.getUntrackedParameter<int>("nCSCHitsMax", 25);
30  lengthMin = pset.getUntrackedParameter<double>("lengthMin", 140.);
31  lengthMax = pset.getUntrackedParameter<double>("lengthMax", 600.);
32  deltaPhiMax = pset.getUntrackedParameter<double>("deltaPhiMax", 0.2);
33  polarMax = pset.getUntrackedParameter<double>("polarMax", 0.7);
34  polarMin = pset.getUntrackedParameter<double>("polarMin", 0.3);
35 
36  // trigger filter
37  useTriggerFilter = pset.getUntrackedParameter<bool>("useTriggerFilter", false);
38 
39  // input tags for collections
40  rd_token = consumes<FEDRawDataCollection>(pset.getParameter<edm::InputTag>("rawDataTag"));
41  sd_token = consumes<CSCStripDigiCollection>(pset.getParameter<edm::InputTag>("stripDigiTag"));
42  wd_token = consumes<CSCWireDigiCollection>(pset.getParameter<edm::InputTag>("wireDigiTag"));
43  cd_token = consumes<CSCComparatorDigiCollection>(pset.getParameter<edm::InputTag>("compDigiTag"));
44  al_token = consumes<CSCALCTDigiCollection>(pset.getParameter<edm::InputTag>("alctDigiTag"));
45  cl_token = consumes<CSCCLCTDigiCollection>(pset.getParameter<edm::InputTag>("clctDigiTag"));
46  co_token = consumes<CSCCorrelatedLCTDigiCollection>(pset.getParameter<edm::InputTag>("corrlctDigiTag"));
47  rh_token = consumes<CSCRecHit2DCollection>(pset.getParameter<edm::InputTag>("cscRecHitTag"));
48  se_token = consumes<CSCSegmentCollection>(pset.getParameter<edm::InputTag>("cscSegTag"));
49  sa_token = consumes<reco::TrackCollection>(pset.getParameter<edm::InputTag>("saMuonTag"));
50  l1_token = consumes<L1MuGMTReadoutCollection>(pset.getParameter<edm::InputTag>("l1aTag"));
51  tr_token = consumes<TriggerResults>(pset.getParameter<edm::InputTag>("hltTag"));
52  sh_token = consumes<PSimHitContainer>(pset.getParameter<edm::InputTag>("simHitTag"));
53 
54  // flags to switch on/off individual modules
55  makeOccupancyPlots = pset.getUntrackedParameter<bool>("makeOccupancyPlots", true);
56  makeTriggerPlots = pset.getUntrackedParameter<bool>("makeTriggerPlots", false);
57  makeStripPlots = pset.getUntrackedParameter<bool>("makeStripPlots", true);
58  makeWirePlots = pset.getUntrackedParameter<bool>("makeWirePlots", true);
59  makeRecHitPlots = pset.getUntrackedParameter<bool>("makeRecHitPlots", true);
60  makeSimHitPlots = pset.getUntrackedParameter<bool>("makeSimHitPlots", true);
61  makeSegmentPlots = pset.getUntrackedParameter<bool>("makeSegmentPlots", true);
62  makeResolutionPlots = pset.getUntrackedParameter<bool>("makeResolutionPlots", true);
63  makePedNoisePlots = pset.getUntrackedParameter<bool>("makePedNoisePlots", true);
64  makeEfficiencyPlots = pset.getUntrackedParameter<bool>("makeEfficiencyPlots", true);
65  makeGasGainPlots = pset.getUntrackedParameter<bool>("makeGasGainPlots", true);
66  makeAFEBTimingPlots = pset.getUntrackedParameter<bool>("makeAFEBTimingPlots", true);
67  makeCompTimingPlots = pset.getUntrackedParameter<bool>("makeCompTimingPlots", true);
68  makeADCTimingPlots = pset.getUntrackedParameter<bool>("makeADCTimingPlots", true);
69  makeRHNoisePlots = pset.getUntrackedParameter<bool>("makeRHNoisePlots", false);
70  makeCalibPlots = pset.getUntrackedParameter<bool>("makeCalibPlots", false);
71  makeStandalonePlots = pset.getUntrackedParameter<bool>("makeStandalonePlots", false);
72  makeTimeMonitorPlots = pset.getUntrackedParameter<bool>("makeTimeMonitorPlots", false);
73  makeHLTPlots = pset.getUntrackedParameter<bool>("makeHLTPlots", false);
74 
75  // set counters to zero
76  nEventsAnalyzed = 0;
77  rhTreeCount = 0;
78  segTreeCount = 0;
79  firstEvent = true;
80 
81  // Create the root file for the histograms
82  theFile = new TFile(rootFileName.c_str(), "RECREATE");
83  theFile->cd();
84 
85  // Create object of class CSCValHists to manage histograms
86  histos = new CSCValHists();
87 
88  // book Occupancy Histos
89  hOWires = new TH2I("hOWires", "Wire Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
90  hOStrips = new TH2I("hOStrips", "Strip Digi Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
91  hORecHits = new TH2I("hORecHits", "RecHit Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
92  hOSegments = new TH2I("hOSegments", "Segments Occupancy", 36, 0.5, 36.5, 20, 0.5, 20.5);
93 
94  // book Eff histos
95  hSSTE = new TH1F("hSSTE", "hSSTE", 40, 0, 40);
96  hRHSTE = new TH1F("hRHSTE", "hRHSTE", 40, 0, 40);
97  hSEff = new TH1F("hSEff", "Segment Efficiency", 20, 0.5, 20.5);
98  hRHEff = new TH1F("hRHEff", "recHit Efficiency", 20, 0.5, 20.5);
99 
100  const int nChambers = 36;
101  const int nTypes = 18;
102  float nCH_min = 0.5;
103  float nCh_max = float(nChambers) + 0.5;
104  float nT_min = 0.5;
105  float nT_max = float(nTypes) + 0.5;
106 
107  hSSTE2 = new TH2F("hSSTE2", "hSSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
108  hRHSTE2 = new TH2F("hRHSTE2", "hRHSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
109  hStripSTE2 = new TH2F("hStripSTE2", "hStripSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
110  hWireSTE2 = new TH2F("hWireSTE2", "hWireSTE2", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
111 
112  hEffDenominator = new TH2F("hEffDenominator", "hEffDenominator", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
113  hSEff2 = new TH2F("hSEff2", "Segment Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
114  hRHEff2 = new TH2F("hRHEff2", "recHit Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
115 
116  hStripEff2 = new TH2F("hStripEff2", "strip Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
117  hWireEff2 = new TH2F("hWireEff2", "wire Efficiency 2D", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
118 
120  new TH2F("hSensitiveAreaEvt", "events in sensitive area", nChambers, nCH_min, nCh_max, nTypes, nT_min, nT_max);
121 
122  // setup trees to hold global position data for rechits and segments
123  if (writeTreeToFile)
124  histos->setupTrees();
125 
126  geomToken_ = esConsumes<CSCGeometry, MuonGeometryRecord>();
127 }

References dtNoiseAnalysis_cfi::detailedAnalysis, amptDefault_cfi::firstEvent, dqmMemoryStats::float, combine::histos, ALCARECOTkAlMinBias_cff::pMin, muonDTDigis_cfi::pset, CSCSkim_cfi::rootFileName, AlCaHLTBitMon_QueryRunRegistry::string, and interactiveExample::theFile.

◆ ~CSCValidation()

CSCValidation::~CSCValidation ( )
override

Destructor.

Definition at line 132 of file CSCValidation.cc.

132  {
133  // produce final efficiency histograms
136  hSEff2->Divide(hSSTE2, hEffDenominator, 1., 1., "B");
137  hRHEff2->Divide(hRHSTE2, hEffDenominator, 1., 1., "B");
138  hStripEff2->Divide(hStripSTE2, hEffDenominator, 1., 1., "B");
139  hWireEff2->Divide(hWireSTE2, hEffDenominator, 1., 1., "B");
140 
141  histos->insertPlot(hRHSTE, "hRHSTE", "Efficiency");
142  histos->insertPlot(hSSTE, "hSSTE", "Efficiency");
143  histos->insertPlot(hSSTE2, "hSSTE2", "Efficiency");
144  histos->insertPlot(hEffDenominator, "hEffDenominator", "Efficiency");
145  histos->insertPlot(hRHSTE2, "hRHSTE2", "Efficiency");
146  histos->insertPlot(hStripSTE2, "hStripSTE2", "Efficiency");
147  histos->insertPlot(hWireSTE2, "hWireSTE2", "Efficiency");
148 
149  //moving this to post job macros
150  histos->insertPlot(hSEff, "hSEff", "Efficiency");
151  histos->insertPlot(hRHEff, "hRHEff", "Efficiency");
152 
153  histos->insertPlot(hSEff2, "hSEff2", "Efficiency");
154  histos->insertPlot(hRHEff2, "hRHEff2", "Efficiency");
155  histos->insertPlot(hStripEff2, "hStripff2", "Efficiency");
156  histos->insertPlot(hWireEff2, "hWireff2", "Efficiency");
157 
158  histos->insertPlot(hSensitiveAreaEvt, "", "Efficiency");
159 
160  // throw in occupancy plots so they're saved
161  histos->insertPlot(hOWires, "hOWires", "Digis");
162  histos->insertPlot(hOStrips, "hOStrips", "Digis");
163  histos->insertPlot(hORecHits, "hORecHits", "recHits");
164  histos->insertPlot(hOSegments, "hOSegments", "Segments");
165 
166  // write histos to the specified file
168  if (writeTreeToFile)
170  theFile->Close();
171 }

References combine::histos, and interactiveExample::theFile.

Member Function Documentation

◆ analyze()

void CSCValidation::analyze ( const edm::Event event,
const edm::EventSetup eventSetup 
)
overridevirtual

Perform the analysis.

Implements edm::EDAnalyzer.

Definition at line 176 of file CSCValidation.cc.

176  {
177  // increment counter
178  nEventsAnalyzed++;
179 
180  //int iRun = event.id().run();
181  //int iEvent = event.id().event();
182 
183  // Get the Digis
190  if (useDigis) {
191  event.getByToken(sd_token, strips);
192  event.getByToken(wd_token, wires);
193  event.getByToken(cd_token, compars);
194  event.getByToken(al_token, alcts);
195  event.getByToken(cl_token, clcts);
196  event.getByToken(co_token, correlatedlcts);
197  }
198 
199  // Get the CSC Geometry :
200  edm::ESHandle<CSCGeometry> cscGeom = eventSetup.getHandle(geomToken_);
201 
202  // Get the RecHits collection :
204  event.getByToken(rh_token, recHits);
205 
206  //CSCRecHit2DCollection::const_iterator recIt;
207  //for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
208  // recIt->print();
209  // }
210 
211  // Get the SimHits (if applicable)
213  if (isSimulation)
214  event.getByToken(sh_token, simHits);
215 
216  // get CSC segment collection
218  event.getByToken(se_token, cscSegments);
219 
220  // get the trigger collection
223  event.getByToken(l1_token, pCollection);
224  }
226  if (makeHLTPlots) {
227  event.getByToken(tr_token, hlt);
228  }
229 
230  // get the standalone muon collection
233  event.getByToken(sa_token, saMuons);
234  }
235 
237  // Run the modules //
239 
240  // Only do this for the first event
241  // this is probably outdated and needs to be looked at
242  if (nEventsAnalyzed == 1 && makeCalibPlots)
243  doCalibrations(eventSetup);
244 
245  // Look at the l1a trigger info (returns true if csc L1A present)
246  bool CSCL1A = false;
248  CSCL1A = doTrigger(pCollection);
249  if (!useTriggerFilter)
250  CSCL1A = true; // always true if not filtering on trigger
251 
252  cleanEvent = false;
255  if (!useQualityFilter)
256  cleanEvent = true; // always true if not filtering on event quality
257 
258  // look at various chamber occupancies
259  // keep this outside of filter for diagnostics???
260  if (makeOccupancyPlots && CSCL1A)
262 
263  if (makeHLTPlots)
264  doHLT(hlt);
265 
266  if (cleanEvent && CSCL1A) {
267  // general look at strip digis
268  if (makeStripPlots && useDigis)
270 
271  // general look at wire digis
272  if (makeWirePlots && useDigis)
274 
275  // general look at rechits
276  if (makeRecHitPlots)
277  doRecHits(recHits, cscGeom);
278 
279  // look at simHits
282 
283  // general look at Segments
284  if (makeSegmentPlots)
285  doSegments(cscSegments, cscGeom);
286 
287  // look at hit resolution
289  doResolution(cscSegments, cscGeom);
290 
291  // look at Pedestal Noise
294 
295  // look at recHit and segment efficiencies
298 
299  // gas gain
300  if (makeGasGainPlots && useDigis)
302 
303  // AFEB timing
306 
307  // Comparators timing
309  doCompTiming(*compars);
310 
311  // strip ADC timing
312  if (makeADCTimingPlots)
314 
315  // recHit Noise
316  if (makeRHNoisePlots && useDigis)
318 
319  // look at standalone muons (not implemented yet)
321  doStandalone(saMuons);
322 
323  // make plots for monitoring the trigger and offline timing
325  doTimeMonitoring(recHits, cscSegments, alcts, clcts, correlatedlcts, pCollection, cscGeom, eventSetup, event);
326 
327  firstEvent = false;
328  }
329 }

References dtChamberEfficiency_cfi::cscSegments, ecalTB2006H4_GenSimDigiReco_cfg::doSimHits, amptDefault_cfi::firstEvent, edm::EventSetup::getHandle(), ValidationMatrix::hlt, FastTrackerRecHitMaskProducer_cfi::recHits, FastTrackerRecHitCombiner_cfi::simHits, DigiDM_cff::strips, and DigiDM_cff::wires.

◆ chamberSerial()

int CSCValidation::chamberSerial ( CSCDetId  id)
private

Definition at line 1358 of file CSCValidation.cc.

1358  {
1359  int st = id.station();
1360  int ri = id.ring();
1361  int ch = id.chamber();
1362  int ec = id.endcap();
1363  int kSerial = ch;
1364  if (st == 1 && ri == 1)
1365  kSerial = ch;
1366  if (st == 1 && ri == 2)
1367  kSerial = ch + 36;
1368  if (st == 1 && ri == 3)
1369  kSerial = ch + 72;
1370  if (st == 1 && ri == 4)
1371  kSerial = ch;
1372  if (st == 2 && ri == 1)
1373  kSerial = ch + 108;
1374  if (st == 2 && ri == 2)
1375  kSerial = ch + 126;
1376  if (st == 3 && ri == 1)
1377  kSerial = ch + 162;
1378  if (st == 3 && ri == 2)
1379  kSerial = ch + 180;
1380  if (st == 4 && ri == 1)
1381  kSerial = ch + 216;
1382  if (st == 4 && ri == 2)
1383  kSerial = ch + 234; // one day...
1384  if (ec == 2)
1385  kSerial = kSerial + 300;
1386  return kSerial;
1387 }

◆ doADCTiming()

void CSCValidation::doADCTiming ( const CSCRecHit2DCollection rechitcltn)
private

Definition at line 2843 of file CSCValidation.cc.

2843  {
2844  float adc_3_3_sum, adc_3_3_wtbin, x, y;
2845  int cfeb, idchamber, ring;
2846 
2847  std::string name, title, endcapstr;
2848  ostringstream ss;
2849  std::vector<float> zer(6, 0.0);
2850 
2851  CSCIndexer indexer;
2852  std::map<int, int>::iterator intIt;
2853 
2854  if (rechitcltn.begin() != rechitcltn.end()) {
2855  // std::cout<<"Event "<<nEventsAnalyzed <<std::endl;
2856 
2857  // Looping thru rechit collection
2860  for (recIt = rechitcltn.begin(); recIt != rechitcltn.end(); ++recIt) {
2861  CSCDetId id = (CSCDetId)(*recIt).cscDetId();
2862  // getting strips comprising rechit
2863  if (recIt->nStrips() == 3) {
2864  // get 3X3 ADC Sum
2865  // get 3X3 ADC Sum
2866  unsigned int binmx = 0;
2867  float adcmax = 0.0;
2868 
2869  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2870  for (unsigned int j = 0; j < recIt->nTimeBins(); j++)
2871  if (recIt->adcs(i, j) > adcmax) {
2872  adcmax = recIt->adcs(i, j);
2873  binmx = j;
2874  }
2875 
2876  adc_3_3_sum = 0.0;
2877  //well, this really only works for 3 strips in readout - not sure the right fix for general case
2878  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2879  for (unsigned int j = binmx - 1; j <= binmx + 1; j++)
2880  adc_3_3_sum += recIt->adcs(i, j);
2881 
2882  // ADC weighted time bin
2883  if (adc_3_3_sum > 100.0) {
2884  int centerStrip = recIt->channels(1); //take central from 3 strips;
2885  // temporary fix
2886  int flag = 0;
2887  if (id.station() == 1 && id.ring() == 4 && centerStrip > 16)
2888  flag = 1;
2889  // end of temporary fix
2890  if (flag == 0) {
2891  adc_3_3_wtbin = (*recIt).tpeak() / 50; //getTiming(strpcltn, id, centerStrip);
2892  idchamber = indexer.dbIndex(id, centerStrip) / 10; //strips 1-16 ME1/1a
2893  // become strips 65-80 ME1/1 !!!
2894  /*
2895  if(id.station()==1 && (id.ring()==1 || id.ring()==4))
2896  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "<<m_strip[1]<<" "<<
2897  " "<<centerStrip<<
2898  " "<<adc_3_3_wtbin<<" "<<adc_3_3_sum<<std::endl;
2899  */
2900  ss << "adc_3_3_weight_time_bin_vs_cfeb_occupancy_ME_" << idchamber;
2901  name = ss.str();
2902  ss.str("");
2903 
2904  std::string endcapstr;
2905  if (id.endcap() == 1)
2906  endcapstr = "+";
2907  if (id.endcap() == 2)
2908  endcapstr = "-";
2909  ring = id.ring();
2910  if (id.ring() == 4)
2911  ring = 1;
2912  ss << "ADC 3X3 Weighted Time Bin vs CFEB Occupancy ME" << endcapstr << id.station() << "/" << ring << "/"
2913  << id.chamber();
2914  title = ss.str();
2915  ss.str("");
2916 
2917  cfeb = (centerStrip - 1) / 16 + 1;
2918  x = cfeb;
2919  y = adc_3_3_wtbin;
2920  histos->fill2DHist(x, y, name, title, 5, 1., 6., 80, -8., 8., "ADCTiming");
2921  } // end of if flag==0
2922  } // end of if (adc_3_3_sum > 100.0)
2923  } // end of if if(m_strip.size()==3
2924  } // end of the pass thru CSCRecHit2DCollection
2925  } // end of if (rechitcltn.begin() != rechitcltn.end())
2926 }

References CSCIndexer::dbIndex(), makeMuonMisalignmentScenario::endcap, RemoveAddSevLevel::flag, combine::histos, mps_fire::i, dqmiolumiharvest::j, Skims_PA_cff::name, relativeConstraints::ring, contentValuesCheck::ss, relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, and runGCPTkAlMap::title.

◆ doAFEBTiming()

void CSCValidation::doAFEBTiming ( const CSCWireDigiCollection wirecltn)
private

Definition at line 2715 of file CSCValidation.cc.

2715  {
2716  ostringstream ss;
2717  std::string name, title, endcapstr;
2718  float x, y;
2719  int wire, wiretbin, nmbwiretbin, layer, afeb, idlayer, idchamber;
2720  int channel = 0; // for CSCIndexer::dbIndex(id, channel); irrelevant here
2721  CSCIndexer indexer;
2722 
2723  if (wirecltn.begin() != wirecltn.end()) {
2724  //std::cout<<std::endl;
2725  //std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2726  //std::cout<<std::endl;
2727 
2728  // cycle on wire collection for all CSC
2730  for (wiredetUnitIt = wirecltn.begin(); wiredetUnitIt != wirecltn.end(); ++wiredetUnitIt) {
2731  const CSCDetId id = (*wiredetUnitIt).first;
2732  idlayer = indexer.dbIndex(id, channel);
2733  idchamber = idlayer / 10;
2734  layer = id.layer();
2735 
2736  if (id.endcap() == 1)
2737  endcapstr = "+";
2738  if (id.endcap() == 2)
2739  endcapstr = "-";
2740 
2741  // looping in the layer of given CSC
2742 
2743  const CSCWireDigiCollection::Range& range = (*wiredetUnitIt).second;
2744  for (CSCWireDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2745  wire = (*digiIt).getWireGroup();
2746  wiretbin = (*digiIt).getTimeBin();
2747  nmbwiretbin = (*digiIt).getTimeBinsOn().size();
2748  afeb = 3 * ((wire - 1) / 8) + (layer + 1) / 2;
2749 
2750  // Anode wire group time bin vs afeb for each CSC
2751  x = afeb;
2752  y = wiretbin;
2753  ss << "afeb_time_bin_vs_afeb_occupancy_ME_" << idchamber;
2754  name = ss.str();
2755  ss.str("");
2756  ss << "Time Bin vs AFEB Occupancy ME" << endcapstr << id.station() << "/" << id.ring() << "/" << id.chamber();
2757  title = ss.str();
2758  ss.str("");
2759  histos->fill2DHist(x, y, name, title, 42, 1., 43., 16, 0., 16., "AFEBTiming");
2760 
2761  // Number of anode wire group time bin vs afeb for each CSC
2762  x = afeb;
2763  y = nmbwiretbin;
2764  ss << "nmb_afeb_time_bins_vs_afeb_ME_" << idchamber;
2765  name = ss.str();
2766  ss.str("");
2767  ss << "Number of Time Bins vs AFEB ME" << endcapstr << id.station() << "/" << id.ring() << "/" << id.chamber();
2768  title = ss.str();
2769  ss.str("");
2770  histos->fill2DHist(x, y, name, title, 42, 1., 43., 16, 0., 16., "AFEBTiming");
2771 
2772  } // end of digis loop in layer
2773  } // end of wire collection loop
2774  } // end of if(wirecltn.begin() != wirecltn.end())
2775 }

References CSCIndexer::dbIndex(), makeMuonMisalignmentScenario::endcap, combine::histos, phase1PixelTopology::layer, Skims_PA_cff::name, FastTimerService_cff::range, contentValuesCheck::ss, AlCaHLTBitMon_QueryRunRegistry::string, and runGCPTkAlMap::title.

◆ doCalibrations()

void CSCValidation::doCalibrations ( const edm::EventSetup eventSetup)
private

Definition at line 693 of file CSCValidation.cc.

693  {
694  // Only do this for the first event
695  if (nEventsAnalyzed == 1) {
696  LogDebug("Calibrations") << "Loading Calibrations...";
697 
698  // get the gains
700  eventSetup.get<CSCDBGainsRcd>().get(hGains);
701  const CSCDBGains* pGains = hGains.product();
702  // get the crosstalks
704  eventSetup.get<CSCDBCrosstalkRcd>().get(hCrosstalk);
705  const CSCDBCrosstalk* pCrosstalk = hCrosstalk.product();
706  // get the noise matrix
707  edm::ESHandle<CSCDBNoiseMatrix> hNoiseMatrix;
708  eventSetup.get<CSCDBNoiseMatrixRcd>().get(hNoiseMatrix);
709  const CSCDBNoiseMatrix* pNoiseMatrix = hNoiseMatrix.product();
710  // get pedestals
712  eventSetup.get<CSCDBPedestalsRcd>().get(hPedestals);
713  const CSCDBPedestals* pPedestals = hPedestals.product();
714 
715  LogDebug("Calibrations") << "Calibrations Loaded!";
716 
717  for (int i = 0; i < 400; i++) {
718  int bin = i + 1;
719  histos->fillCalibHist(pGains->gains[i].gain_slope, "hCalibGainsS", "Gains Slope", 400, 0, 400, bin, "Calib");
721  pCrosstalk->crosstalk[i].xtalk_slope_left, "hCalibXtalkSL", "Xtalk Slope Left", 400, 0, 400, bin, "Calib");
723  pCrosstalk->crosstalk[i].xtalk_slope_right, "hCalibXtalkSR", "Xtalk Slope Right", 400, 0, 400, bin, "Calib");
724  histos->fillCalibHist(pCrosstalk->crosstalk[i].xtalk_intercept_left,
725  "hCalibXtalkIL",
726  "Xtalk Intercept Left",
727  400,
728  0,
729  400,
730  bin,
731  "Calib");
732  histos->fillCalibHist(pCrosstalk->crosstalk[i].xtalk_intercept_right,
733  "hCalibXtalkIR",
734  "Xtalk Intercept Right",
735  400,
736  0,
737  400,
738  bin,
739  "Calib");
740  histos->fillCalibHist(pPedestals->pedestals[i].ped, "hCalibPedsP", "Peds", 400, 0, 400, bin, "Calib");
741  histos->fillCalibHist(pPedestals->pedestals[i].rms, "hCalibPedsR", "Peds RMS", 400, 0, 400, bin, "Calib");
743  pNoiseMatrix->matrix[i].elem33, "hCalibNoise33", "Noise Matrix 33", 400, 0, 400, bin, "Calib");
745  pNoiseMatrix->matrix[i].elem34, "hCalibNoise34", "Noise Matrix 34", 400, 0, 400, bin, "Calib");
747  pNoiseMatrix->matrix[i].elem35, "hCalibNoise35", "Noise Matrix 35", 400, 0, 400, bin, "Calib");
749  pNoiseMatrix->matrix[i].elem44, "hCalibNoise44", "Noise Matrix 44", 400, 0, 400, bin, "Calib");
751  pNoiseMatrix->matrix[i].elem45, "hCalibNoise45", "Noise Matrix 45", 400, 0, 400, bin, "Calib");
753  pNoiseMatrix->matrix[i].elem46, "hCalibNoise46", "Noise Matrix 46", 400, 0, 400, bin, "Calib");
755  pNoiseMatrix->matrix[i].elem55, "hCalibNoise55", "Noise Matrix 55", 400, 0, 400, bin, "Calib");
757  pNoiseMatrix->matrix[i].elem56, "hCalibNoise56", "Noise Matrix 56", 400, 0, 400, bin, "Calib");
759  pNoiseMatrix->matrix[i].elem57, "hCalibNoise57", "Noise Matrix 57", 400, 0, 400, bin, "Calib");
761  pNoiseMatrix->matrix[i].elem66, "hCalibNoise66", "Noise Matrix 66", 400, 0, 400, bin, "Calib");
763  pNoiseMatrix->matrix[i].elem67, "hCalibNoise67", "Noise Matrix 67", 400, 0, 400, bin, "Calib");
765  pNoiseMatrix->matrix[i].elem77, "hCalibNoise77", "Noise Matrix 77", 400, 0, 400, bin, "Calib");
766  }
767  }
768 }

References newFWLiteAna::bin, CSCDBCrosstalk::crosstalk, CSCDBGains::gains, edm::EventSetup::get(), get, combine::histos, mps_fire::i, LogDebug, CSCDBNoiseMatrix::matrix, CSCDBPedestals::pedestals, and edm::ESHandle< T >::product().

◆ doCompTiming()

void CSCValidation::doCompTiming ( const CSCComparatorDigiCollection compars)
private

Definition at line 2782 of file CSCValidation.cc.

2782  {
2783  ostringstream ss;
2785  float x, y;
2786  int strip, tbin, cfeb, idlayer, idchamber;
2787  int channel = 0; // for CSCIndexer::dbIndex(id, channel); irrelevant here
2788  CSCIndexer indexer;
2789 
2790  if (compars.begin() != compars.end()) {
2791  //std::cout<<std::endl;
2792  //std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2793  //std::cout<<std::endl;
2794 
2795  // cycle on comparators collection for all CSC
2797  for (compdetUnitIt = compars.begin(); compdetUnitIt != compars.end(); ++compdetUnitIt) {
2798  const CSCDetId id = (*compdetUnitIt).first;
2799  idlayer = indexer.dbIndex(id, channel); // channel irrelevant here
2800  idchamber = idlayer / 10;
2801 
2802  if (id.endcap() == 1)
2803  endcap = "+";
2804  if (id.endcap() == 2)
2805  endcap = "-";
2806  // looping in the layer of given CSC
2807  const CSCComparatorDigiCollection::Range& range = (*compdetUnitIt).second;
2808  for (CSCComparatorDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2809  strip = (*digiIt).getStrip();
2810  /*
2811  if(id.station()==1 && (id.ring()==1 || id.ring()==4))
2812  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "
2813  <<strip <<std::endl;
2814  */
2815  indexer.dbIndex(id, strip); // strips 1-16 of ME1/1a
2816  // become strips 65-80 of ME1/1
2817  tbin = (*digiIt).getTimeBin();
2818  cfeb = (strip - 1) / 16 + 1;
2819 
2820  // time bin vs cfeb for each CSC
2821 
2822  x = cfeb;
2823  y = tbin;
2824  ss << "comp_time_bin_vs_cfeb_occupancy_ME_" << idchamber;
2825  name = ss.str();
2826  ss.str("");
2827  ss << "Comparator Time Bin vs CFEB Occupancy ME" << endcap << id.station() << "/" << id.ring() << "/"
2828  << id.chamber();
2829  title = ss.str();
2830  ss.str("");
2831  histos->fill2DHist(x, y, name, title, 5, 1., 6., 16, 0., 16., "CompTiming");
2832 
2833  } // end of digis loop in layer
2834  } // end of collection loop
2835  } // end of if(compars.begin() !=compars.end())
2836 }

References CSCIndexer::dbIndex(), makeMuonMisalignmentScenario::endcap, combine::histos, Skims_PA_cff::name, FastTimerService_cff::range, contentValuesCheck::ss, AlCaHLTBitMon_QueryRunRegistry::string, digitizers_cfi::strip, and runGCPTkAlMap::title.

◆ doEfficiencies()

void CSCValidation::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 1462 of file CSCValidation.cc.

1466  {
1467  bool allWires[2][4][4][36][6];
1468  bool allStrips[2][4][4][36][6];
1469  bool AllRecHits[2][4][4][36][6];
1470  bool AllSegments[2][4][4][36];
1471 
1472  //bool MultiSegments[2][4][4][36];
1473  for (int iE = 0; iE < 2; iE++) {
1474  for (int iS = 0; iS < 4; iS++) {
1475  for (int iR = 0; iR < 4; iR++) {
1476  for (int iC = 0; iC < 36; iC++) {
1477  AllSegments[iE][iS][iR][iC] = false;
1478  //MultiSegments[iE][iS][iR][iC] = false;
1479  for (int iL = 0; iL < 6; iL++) {
1480  allWires[iE][iS][iR][iC][iL] = false;
1481  allStrips[iE][iS][iR][iC][iL] = false;
1482  AllRecHits[iE][iS][iR][iC][iL] = false;
1483  }
1484  }
1485  }
1486  }
1487  }
1488 
1489  if (useDigis) {
1490  // Wires
1491  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
1492  CSCDetId idrec = (CSCDetId)(*dWDiter).first;
1493  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
1494  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
1495  for (; wireIter != lWire; ++wireIter) {
1496  allWires[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1497  true;
1498  break;
1499  }
1500  }
1501 
1502  //---- STRIPS
1503  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
1504  CSCDetId idrec = (CSCDetId)(*dSDiter).first;
1505  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
1506  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
1507  for (; stripIter != lStrip; ++stripIter) {
1508  std::vector<int> myADCVals = stripIter->getADCCounts();
1509  bool thisStripFired = false;
1510  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1511  float threshold = 13.3;
1512  float diff = 0.;
1513  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
1514  diff = (float)myADCVals[iCount] - thisPedestal;
1515  if (diff > threshold) {
1516  thisStripFired = true;
1517  break;
1518  }
1519  }
1520  if (thisStripFired) {
1521  allStrips[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1522  true;
1523  break;
1524  }
1525  }
1526  }
1527  }
1528 
1529  // Rechits
1530  for (CSCRecHit2DCollection::const_iterator recEffIt = recHits->begin(); recEffIt != recHits->end(); recEffIt++) {
1531  //CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
1532  CSCDetId idrec = (CSCDetId)(*recEffIt).cscDetId();
1533  AllRecHits[idrec.endcap() - 1][idrec.station() - 1][idrec.ring() - 1][idrec.chamber() - 1][idrec.layer() - 1] =
1534  true;
1535  }
1536 
1537  std::vector<unsigned int> seg_ME2(2, 0);
1538  std::vector<unsigned int> seg_ME3(2, 0);
1539  std::vector<std::pair<CSCDetId, CSCSegment> > theSegments(4);
1540  // Segments
1541  for (CSCSegmentCollection::const_iterator segEffIt = cscSegments->begin(); segEffIt != cscSegments->end();
1542  segEffIt++) {
1543  CSCDetId idseg = (CSCDetId)(*segEffIt).cscDetId();
1544  //if(AllSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()]){
1545  //MultiSegments[idrec.endcap() -1][idrec.station() -1][idrec.ring() -1][idrec.chamber()] = true;
1546  //}
1547  AllSegments[idseg.endcap() - 1][idseg.station() - 1][idseg.ring() - 1][idseg.chamber() - 1] = true;
1548  // "Intrinsic" efficiency measurement relies on "good" segment extrapolation - we need the pre-selection below
1549  // station 2 "good" segment will be used for testing efficiencies in ME1 and ME3
1550  // station 3 "good" segment will be used for testing efficiencies in ME2 and ME4
1551  if (2 == idseg.station() || 3 == idseg.station()) {
1552  unsigned int seg_tmp;
1553  if (2 == idseg.station()) {
1554  ++seg_ME2[idseg.endcap() - 1];
1555  seg_tmp = seg_ME2[idseg.endcap() - 1];
1556  } else {
1557  ++seg_ME3[idseg.endcap() - 1];
1558  seg_tmp = seg_ME3[idseg.endcap() - 1];
1559  }
1560  // is the segment good
1561  if (1 == seg_tmp && 6 == (*segEffIt).nRecHits() && (*segEffIt).chi2() / (*segEffIt).degreesOfFreedom() < 3.) {
1562  std::pair<CSCDetId, CSCSegment> specSeg = make_pair((CSCDetId)(*segEffIt).cscDetId(), *segEffIt);
1563  theSegments[2 * (idseg.endcap() - 1) + (idseg.station() - 2)] = specSeg;
1564  }
1565  }
1566  /*
1567  if(2==idseg.station()){
1568  ++seg_ME2[idseg.endcap() -1];
1569  if(1==seg_ME2[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1570  std::pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1571  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1572  }
1573  }
1574  else if(3==idseg.station()){
1575  ++seg_ME3[idseg.endcap() -1];
1576  if(1==seg_ME3[idseg.endcap() -1] && 6==(*segEffIt).nRecHits() && (*segEffIt).chi2()/(*segEffIt).degreesOfFreedom()<3.){
1577  std::pair <CSCDetId, CSCSegment> specSeg = make_pair( (CSCDetId)(*segEffIt).cscDetId(),*segEffIt);
1578  theSegments[2*(idseg.endcap()-1)+(idseg.station() -2)] = specSeg;
1579  }
1580  }
1581  */
1582  }
1583  // Simple efficiency calculations
1584  for (int iE = 0; iE < 2; iE++) {
1585  for (int iS = 0; iS < 4; iS++) {
1586  for (int iR = 0; iR < 4; iR++) {
1587  for (int iC = 0; iC < 36; iC++) {
1588  int NumberOfLayers = 0;
1589  for (int iL = 0; iL < 6; iL++) {
1590  if (AllRecHits[iE][iS][iR][iC][iL]) {
1591  NumberOfLayers++;
1592  }
1593  }
1594  int bin = 0;
1595  if (iS == 0)
1596  bin = iR + 1 + (iE * 10);
1597  else
1598  bin = (iS + 1) * 2 + (iR + 1) + (iE * 10);
1599  if (NumberOfLayers > 1) {
1600  //if(!(MultiSegments[iE][iS][iR][iC])){
1601  if (AllSegments[iE][iS][iR][iC]) {
1602  //---- Efficient segment evenents
1603  hSSTE->AddBinContent(bin);
1604  }
1605  //---- All segment events (normalization)
1606  hSSTE->AddBinContent(20 + bin);
1607  //}
1608  }
1609  if (AllSegments[iE][iS][iR][iC]) {
1610  if (NumberOfLayers == 6) {
1611  //---- Efficient rechit events
1612  hRHSTE->AddBinContent(bin);
1613  ;
1614  }
1615  //---- All rechit events (normalization)
1616  hRHSTE->AddBinContent(20 + bin);
1617  ;
1618  }
1619  }
1620  }
1621  }
1622  }
1623 
1624  // pick a segment only if there are no others in the station
1625  std::vector<std::pair<CSCDetId, CSCSegment>*> theSeg;
1626  if (1 == seg_ME2[0])
1627  theSeg.push_back(&theSegments[0]);
1628  if (1 == seg_ME3[0])
1629  theSeg.push_back(&theSegments[1]);
1630  if (1 == seg_ME2[1])
1631  theSeg.push_back(&theSegments[2]);
1632  if (1 == seg_ME3[1])
1633  theSeg.push_back(&theSegments[3]);
1634 
1635  // Needed for plots
1636  // at the end the chamber types will be numbered as 1 to 18
1637  // (ME-4/1, -ME3/2, -ME3/1, ..., +ME3/1, +ME3/2, ME+4/1 )
1638  std::map<std::string, float> chamberTypes;
1639  chamberTypes["ME1/a"] = 0.5;
1640  chamberTypes["ME1/b"] = 1.5;
1641  chamberTypes["ME1/2"] = 2.5;
1642  chamberTypes["ME1/3"] = 3.5;
1643  chamberTypes["ME2/1"] = 4.5;
1644  chamberTypes["ME2/2"] = 5.5;
1645  chamberTypes["ME3/1"] = 6.5;
1646  chamberTypes["ME3/2"] = 7.5;
1647  chamberTypes["ME4/1"] = 8.5;
1648 
1649  if (!theSeg.empty()) {
1650  std::map<int, GlobalPoint> extrapolatedPoint;
1651  std::map<int, GlobalPoint>::iterator it;
1652  const CSCGeometry::ChamberContainer& ChamberContainer = cscGeom->chambers();
1653  // Pick which chamber with which segment to test
1654  for (size_t nCh = 0; nCh < ChamberContainer.size(); nCh++) {
1655  const CSCChamber* cscchamber = ChamberContainer[nCh];
1656  std::pair<CSCDetId, CSCSegment>* thisSegment = nullptr;
1657  for (size_t iSeg = 0; iSeg < theSeg.size(); ++iSeg) {
1658  if (cscchamber->id().endcap() == theSeg[iSeg]->first.endcap()) {
1659  if (1 == cscchamber->id().station() || 3 == cscchamber->id().station()) {
1660  if (2 == theSeg[iSeg]->first.station()) {
1661  thisSegment = theSeg[iSeg];
1662  }
1663  } else if (2 == cscchamber->id().station() || 4 == cscchamber->id().station()) {
1664  if (3 == theSeg[iSeg]->first.station()) {
1665  thisSegment = theSeg[iSeg];
1666  }
1667  }
1668  }
1669  }
1670  // this chamber is to be tested with thisSegment
1671  if (thisSegment) {
1672  CSCSegment* seg = &(thisSegment->second);
1673  const CSCChamber* segChamber = cscGeom->chamber(thisSegment->first);
1674  LocalPoint localCenter(0., 0., 0);
1675  GlobalPoint cscchamberCenter = cscchamber->toGlobal(localCenter);
1676  // try to save some time (extrapolate a segment to a certain position only once)
1677  it = extrapolatedPoint.find(int(cscchamberCenter.z()));
1678  if (it == extrapolatedPoint.end()) {
1679  GlobalPoint segPos = segChamber->toGlobal(seg->localPosition());
1680  GlobalVector segDir = segChamber->toGlobal(seg->localDirection());
1681  double paramaterLine = lineParametrization(segPos.z(), cscchamberCenter.z(), segDir.z());
1682  double xExtrapolated = extrapolate1D(segPos.x(), segDir.x(), paramaterLine);
1683  double yExtrapolated = extrapolate1D(segPos.y(), segDir.y(), paramaterLine);
1684  GlobalPoint globP(xExtrapolated, yExtrapolated, cscchamberCenter.z());
1685  extrapolatedPoint[int(cscchamberCenter.z())] = globP;
1686  }
1687  // Where does the extrapolated point lie in the (tested) chamber local frame? Here:
1688  LocalPoint extrapolatedPointLocal = cscchamber->toLocal(extrapolatedPoint[int(cscchamberCenter.z())]);
1689  const CSCLayer* layer_p = cscchamber->layer(1); //layer 1
1690  const CSCLayerGeometry* layerGeom = layer_p->geometry();
1691  const std::array<const float, 4>& layerBounds = layerGeom->parameters();
1692  float shiftFromEdge = 15.; //cm
1693  float shiftFromDeadZone = 10.;
1694  // is the extrapolated point within a sensitive region
1695  bool pass = withinSensitiveRegion(extrapolatedPointLocal,
1696  layerBounds,
1697  cscchamber->id().station(),
1698  cscchamber->id().ring(),
1699  shiftFromEdge,
1700  shiftFromDeadZone);
1701  if (pass) { // the extrapolation point of the segment lies within sensitive region of that chamber
1702  // how many rechit layers are there in the chamber?
1703  // 0 - maybe the muon died or is deflected at large angle? do not use that case
1704  // 1 - could be noise...
1705  // 2 or more - this is promissing; this is our definition of a reliable signal; use it below
1706  // is other definition better?
1707  int nRHLayers = 0;
1708  for (int iL = 0; iL < 6; ++iL) {
1709  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1710  [cscchamber->id().chamber() - 1][iL]) {
1711  ++nRHLayers;
1712  }
1713  }
1714  //std::cout<<" nRHLayers = "<<nRHLayers<<std::endl;
1715  float verticalScale = chamberTypes[cscchamber->specs()->chamberTypeName()];
1716  if (cscchamberCenter.z() < 0) {
1717  verticalScale = -verticalScale;
1718  }
1719  verticalScale += 9.5;
1720  hSensitiveAreaEvt->Fill(float(cscchamber->id().chamber()), verticalScale);
1721  if (nRHLayers > 1) { // this chamber contains a reliable signal
1722  //chamberTypes[cscchamber->specs()->chamberTypeName()];
1723  // "intrinsic" efficiencies
1724  //std::cout<<" verticalScale = "<<verticalScale<<" chType = "<<cscchamber->specs()->chamberTypeName()<<std::endl;
1725  // this is the denominator forr all efficiencies
1726  hEffDenominator->Fill(float(cscchamber->id().chamber()), verticalScale);
1727  // Segment efficiency
1728  if (AllSegments[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1729  [cscchamber->id().chamber() - 1]) {
1730  hSSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale));
1731  }
1732 
1733  for (int iL = 0; iL < 6; ++iL) {
1734  float weight = 1. / 6.;
1735  // one shold account for the weight in the efficiency...
1736  // Rechit efficiency
1737  if (AllRecHits[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1738  [cscchamber->id().chamber() - 1][iL]) {
1739  hRHSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1740  }
1741  if (useDigis) {
1742  // Wire efficiency
1743  if (allWires[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1][cscchamber->id().ring() - 1]
1744  [cscchamber->id().chamber() - 1][iL]) {
1745  // one shold account for the weight in the efficiency...
1746  hWireSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1747  }
1748  // Strip efficiency
1749  if (allStrips[cscchamber->id().endcap() - 1][cscchamber->id().station() - 1]
1750  [cscchamber->id().ring() - 1][cscchamber->id().chamber() - 1][iL]) {
1751  // one shold account for the weight in the efficiency...
1752  hStripSTE2->Fill(float(cscchamber->id().chamber()), float(verticalScale), weight);
1753  }
1754  }
1755  }
1756  }
1757  }
1758  }
1759  }
1760  }
1761  //
1762 }

References newFWLiteAna::bin, CSCDetId::chamber(), CSCGeometry::chamber(), CSCGeometry::chambers(), CSCChamberSpecs::chamberTypeName(), dtChamberEfficiency_cfi::cscSegments, change_name::diff, CSCDetId::endcap(), first, dqmMemoryStats::float, cms::cuda::for(), CSCLayer::geometry(), CSCChamber::id(), createfilelist::int, CSCChamber::layer(), CSCDetId::layer(), CSCSegment::localDirection(), CSCSegment::localPosition(), TrapezoidalPlaneBounds::parameters(), FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), CSCChamber::specs(), CSCDetId::station(), DigiDM_cff::strips, remoteMonitoring_LED_IterMethod_cfg::threshold, GeomDet::toGlobal(), GeomDet::toLocal(), mps_merge::weight, DigiDM_cff::wires, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

◆ doGasGain()

void CSCValidation::doGasGain ( const CSCWireDigiCollection wirecltn,
const CSCStripDigiCollection strpcltn,
const CSCRecHit2DCollection rechitcltn 
)
private

Definition at line 2442 of file CSCValidation.cc.

2444  {
2445  int channel = 0, mult, wire, layer, idlayer, idchamber, ring;
2446  int wire_strip_rechit_present;
2447  std::string name, title, endcapstr;
2448  ostringstream ss;
2449  CSCIndexer indexer;
2450  std::map<int, int>::iterator intIt;
2451 
2452  m_single_wire_layer.clear();
2453 
2454  if (firstEvent) {
2455  // HV segments, their # and location in terms of wire groups
2456 
2457  m_wire_hvsegm.clear();
2458  std::map<int, std::vector<int> >::iterator intvecIt;
2459  // ME1a ME1b ME1/2 ME1/3 ME2/1 ME2/2 ME3/1 ME3/2 ME4/1 ME4/2
2460  int csctype[10] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10};
2461  int hvsegm_layer[10] = {1, 1, 3, 3, 3, 5, 3, 5, 3, 5};
2462  int id;
2463  nmbhvsegm.clear();
2464  for (int i = 0; i < 10; i++)
2465  nmbhvsegm.push_back(hvsegm_layer[i]);
2466  // For ME1/1a
2467  std::vector<int> zer_1_1a(49, 0);
2468  id = csctype[0];
2469  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2470  m_wire_hvsegm[id] = zer_1_1a;
2471  intvecIt = m_wire_hvsegm.find(id);
2472  for (int wire = 1; wire <= 48; wire++)
2473  intvecIt->second[wire] = 1; // Segment 1
2474 
2475  // For ME1/1b
2476  std::vector<int> zer_1_1b(49, 0);
2477  id = csctype[1];
2478  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2479  m_wire_hvsegm[id] = zer_1_1b;
2480  intvecIt = m_wire_hvsegm.find(id);
2481  for (int wire = 1; wire <= 48; wire++)
2482  intvecIt->second[wire] = 1; // Segment 1
2483 
2484  // For ME1/2
2485  std::vector<int> zer_1_2(65, 0);
2486  id = csctype[2];
2487  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2488  m_wire_hvsegm[id] = zer_1_2;
2489  intvecIt = m_wire_hvsegm.find(id);
2490  for (int wire = 1; wire <= 24; wire++)
2491  intvecIt->second[wire] = 1; // Segment 1
2492  for (int wire = 25; wire <= 48; wire++)
2493  intvecIt->second[wire] = 2; // Segment 2
2494  for (int wire = 49; wire <= 64; wire++)
2495  intvecIt->second[wire] = 3; // Segment 3
2496 
2497  // For ME1/3
2498  std::vector<int> zer_1_3(33, 0);
2499  id = csctype[3];
2500  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2501  m_wire_hvsegm[id] = zer_1_3;
2502  intvecIt = m_wire_hvsegm.find(id);
2503  for (int wire = 1; wire <= 12; wire++)
2504  intvecIt->second[wire] = 1; // Segment 1
2505  for (int wire = 13; wire <= 22; wire++)
2506  intvecIt->second[wire] = 2; // Segment 2
2507  for (int wire = 23; wire <= 32; wire++)
2508  intvecIt->second[wire] = 3; // Segment 3
2509 
2510  // For ME2/1
2511  std::vector<int> zer_2_1(113, 0);
2512  id = csctype[4];
2513  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2514  m_wire_hvsegm[id] = zer_2_1;
2515  intvecIt = m_wire_hvsegm.find(id);
2516  for (int wire = 1; wire <= 44; wire++)
2517  intvecIt->second[wire] = 1; // Segment 1
2518  for (int wire = 45; wire <= 80; wire++)
2519  intvecIt->second[wire] = 2; // Segment 2
2520  for (int wire = 81; wire <= 112; wire++)
2521  intvecIt->second[wire] = 3; // Segment 3
2522 
2523  // For ME2/2
2524  std::vector<int> zer_2_2(65, 0);
2525  id = csctype[5];
2526  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2527  m_wire_hvsegm[id] = zer_2_2;
2528  intvecIt = m_wire_hvsegm.find(id);
2529  for (int wire = 1; wire <= 16; wire++)
2530  intvecIt->second[wire] = 1; // Segment 1
2531  for (int wire = 17; wire <= 28; wire++)
2532  intvecIt->second[wire] = 2; // Segment 2
2533  for (int wire = 29; wire <= 40; wire++)
2534  intvecIt->second[wire] = 3; // Segment 3
2535  for (int wire = 41; wire <= 52; wire++)
2536  intvecIt->second[wire] = 4; // Segment 4
2537  for (int wire = 53; wire <= 64; wire++)
2538  intvecIt->second[wire] = 5; // Segment 5
2539 
2540  // For ME3/1
2541  std::vector<int> zer_3_1(97, 0);
2542  id = csctype[6];
2543  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2544  m_wire_hvsegm[id] = zer_3_1;
2545  intvecIt = m_wire_hvsegm.find(id);
2546  for (int wire = 1; wire <= 32; wire++)
2547  intvecIt->second[wire] = 1; // Segment 1
2548  for (int wire = 33; wire <= 64; wire++)
2549  intvecIt->second[wire] = 2; // Segment 2
2550  for (int wire = 65; wire <= 96; wire++)
2551  intvecIt->second[wire] = 3; // Segment 3
2552 
2553  // For ME3/2
2554  std::vector<int> zer_3_2(65, 0);
2555  id = csctype[7];
2556  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2557  m_wire_hvsegm[id] = zer_3_2;
2558  intvecIt = m_wire_hvsegm.find(id);
2559  for (int wire = 1; wire <= 16; wire++)
2560  intvecIt->second[wire] = 1; // Segment 1
2561  for (int wire = 17; wire <= 28; wire++)
2562  intvecIt->second[wire] = 2; // Segment 2
2563  for (int wire = 29; wire <= 40; wire++)
2564  intvecIt->second[wire] = 3; // Segment 3
2565  for (int wire = 41; wire <= 52; wire++)
2566  intvecIt->second[wire] = 4; // Segment 4
2567  for (int wire = 53; wire <= 64; wire++)
2568  intvecIt->second[wire] = 5; // Segment 5
2569 
2570  // For ME4/1
2571  std::vector<int> zer_4_1(97, 0);
2572  id = csctype[8];
2573  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2574  m_wire_hvsegm[id] = zer_4_1;
2575  intvecIt = m_wire_hvsegm.find(id);
2576  for (int wire = 1; wire <= 32; wire++)
2577  intvecIt->second[wire] = 1; // Segment 1
2578  for (int wire = 33; wire <= 64; wire++)
2579  intvecIt->second[wire] = 2; // Segment 2
2580  for (int wire = 65; wire <= 96; wire++)
2581  intvecIt->second[wire] = 3; // Segment 3
2582 
2583  // For ME4/2
2584  std::vector<int> zer_4_2(65, 0);
2585  id = csctype[9];
2586  if (m_wire_hvsegm.find(id) == m_wire_hvsegm.end())
2587  m_wire_hvsegm[id] = zer_4_2;
2588  intvecIt = m_wire_hvsegm.find(id);
2589  for (int wire = 1; wire <= 16; wire++)
2590  intvecIt->second[wire] = 1; // Segment 1
2591  for (int wire = 17; wire <= 28; wire++)
2592  intvecIt->second[wire] = 2; // Segment 2
2593  for (int wire = 29; wire <= 40; wire++)
2594  intvecIt->second[wire] = 3; // Segment 3
2595  for (int wire = 41; wire <= 52; wire++)
2596  intvecIt->second[wire] = 4; // Segment 4
2597  for (int wire = 53; wire <= 64; wire++)
2598  intvecIt->second[wire] = 5; // Segment 5
2599 
2600  } // end of if(nEventsAnalyzed==1)
2601 
2602  // do wires, strips and rechits present?
2603  wire_strip_rechit_present = 0;
2604  if (wirecltn.begin() != wirecltn.end())
2605  wire_strip_rechit_present = wire_strip_rechit_present + 1;
2606  if (strpcltn.begin() != strpcltn.end())
2607  wire_strip_rechit_present = wire_strip_rechit_present + 2;
2608  if (rechitcltn.begin() != rechitcltn.end())
2609  wire_strip_rechit_present = wire_strip_rechit_present + 4;
2610 
2611  if (wire_strip_rechit_present == 7) {
2612  // std::cout<<"Event "<<nEventsAnalyzed<<std::endl;
2613  // std::cout<<std::endl;
2614 
2615  // cycle on wire collection for all CSC to select single wire hit layers
2617 
2618  for (wiredetUnitIt = wirecltn.begin(); wiredetUnitIt != wirecltn.end(); ++wiredetUnitIt) {
2619  const CSCDetId id = (*wiredetUnitIt).first;
2620  idlayer = indexer.dbIndex(id, channel);
2621  // looping in the layer of given CSC
2622  mult = 0;
2623  wire = 0;
2624  const CSCWireDigiCollection::Range& range = (*wiredetUnitIt).second;
2625  for (CSCWireDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
2626  wire = (*digiIt).getWireGroup();
2627  mult++;
2628  } // end of digis loop in layer
2629 
2630  // select layers with single wire hit
2631  if (mult == 1) {
2632  if (m_single_wire_layer.find(idlayer) == m_single_wire_layer.end())
2633  m_single_wire_layer[idlayer] = wire;
2634  } // end of if(mult==1)
2635  } // end of cycle on detUnit
2636 
2637  // Looping thru rechit collection
2640 
2641  for (recIt = rechitcltn.begin(); recIt != rechitcltn.end(); ++recIt) {
2642  CSCDetId id = (CSCDetId)(*recIt).cscDetId();
2643  idlayer = indexer.dbIndex(id, channel);
2644  idchamber = idlayer / 10;
2645  layer = id.layer();
2646  // select layer with single wire rechit
2647  if (m_single_wire_layer.find(idlayer) != m_single_wire_layer.end()) {
2648  if (recIt->nStrips() == 3) {
2649  // get 3X3 ADC Sum
2650  unsigned int binmx = 0;
2651  float adcmax = 0.0;
2652 
2653  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2654  for (unsigned int j = 0; j < recIt->nTimeBins(); j++)
2655  if (recIt->adcs(i, j) > adcmax) {
2656  adcmax = recIt->adcs(i, j);
2657  binmx = j;
2658  }
2659 
2660  float adc_3_3_sum = 0.0;
2661  //well, this really only works for 3 strips in readout - not sure the right fix for general case
2662  for (unsigned int i = 0; i < recIt->nStrips(); i++)
2663  for (unsigned int j = binmx - 1; j <= binmx + 1; j++)
2664  adc_3_3_sum += recIt->adcs(i, j);
2665 
2666  if (adc_3_3_sum > 0.0 && adc_3_3_sum < 2000.0) {
2667  // temporary fix for ME1/1a to avoid triple entries
2668  int flag = 0;
2669  if (id.station() == 1 && id.ring() == 4 && recIt->channels(1) > 16)
2670  flag = 1;
2671  // end of temporary fix
2672  if (flag == 0) {
2673  wire = m_single_wire_layer[idlayer];
2674  int chambertype = id.iChamberType(id.station(), id.ring());
2675  int hvsgmtnmb = m_wire_hvsegm[chambertype][wire];
2676  int nmbofhvsegm = nmbhvsegm[chambertype - 1];
2677  int location = (layer - 1) * nmbofhvsegm + hvsgmtnmb;
2678 
2679  ss << "gas_gain_rechit_adc_3_3_sum_location_ME_" << idchamber;
2680  name = ss.str();
2681  ss.str("");
2682  if (id.endcap() == 1)
2683  endcapstr = "+";
2684  ring = id.ring();
2685  if (id.station() == 1 && id.ring() == 4)
2686  ring = 1;
2687  if (id.endcap() == 2)
2688  endcapstr = "-";
2689  ss << "Gas Gain Rechit ADC3X3 Sum ME" << endcapstr << id.station() << "/" << ring << "/" << id.chamber();
2690  title = ss.str();
2691  ss.str("");
2692  float x = location;
2693  float y = adc_3_3_sum;
2694  histos->fill2DHist(x, y, name, title, 30, 1.0, 31.0, 50, 0.0, 2000.0, "GasGain");
2695 
2696  /*
2697  std::cout<<idchamber<<" "<<id.station()<<" "<<id.ring()<<" "
2698  <<id.chamber()<<" "<<layer<<" "<< wire<<" "<<m_strip[1]<<" "<<
2699  chambertype<<" "<< hvsgmtnmb<<" "<< nmbofhvsegm<<" "<<
2700  location<<" "<<adc_3_3_sum<<std::endl;
2701  */
2702  } // end of if flag==0
2703  } // end if(adcsum>0.0 && adcsum<2000.0)
2704  } // end of if if(m_strip.size()==3
2705  } // end of if single wire
2706  } // end of looping thru rechit collection
2707  } // end of if wire and strip and rechit present
2708 }

References CSCIndexer::dbIndex(), makeMuonMisalignmentScenario::endcap, amptDefault_cfi::firstEvent, RemoveAddSevLevel::flag, cms::cuda::for(), combine::histos, mps_fire::i, triggerObjects_cff::id, dqmiolumiharvest::j, phase1PixelTopology::layer, EcalCondDBWriter_cfi::location, VarParsing::mult, Skims_PA_cff::name, FastTimerService_cff::range, relativeConstraints::ring, contentValuesCheck::ss, relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, and runGCPTkAlMap::title.

◆ doHLT()

bool CSCValidation::doHLT ( edm::Handle< edm::TriggerResults hltResults)
private

Definition at line 676 of file CSCValidation.cc.

676  {
677  // HLT stuff
678  int hltSize = hlt->size();
679  for (int i = 0; i < hltSize; ++i) {
680  if (hlt->accept(i))
681  histos->fill1DHist(i, "hltBits", "HLT Trigger Bits", hltSize + 1, -0.5, (float)hltSize + 0.5, "Trigger");
682  }
683 
684  return true;
685 }

References combine::histos, ValidationMatrix::hlt, and mps_fire::i.

◆ doNoiseHits()

void CSCValidation::doNoiseHits ( edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments,
edm::ESHandle< CSCGeometry cscGeom,
edm::Handle< CSCStripDigiCollection strips 
)
private

Definition at line 1965 of file CSCValidation.cc.

1968  {
1970  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
1971  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
1972 
1973  //Store the Rechits into a Map
1974  AllRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idrec, *recIt));
1975 
1976  // Find the strip containing this hit
1977  int centerid = recIt->nStrips() / 2;
1978  int centerStrip = recIt->channels(centerid);
1979 
1980  float rHsignal = getthisSignal(*strips, idrec, centerStrip);
1981  histos->fill1DHist(
1982  rHsignal, "hrHSignal", "Signal in the 4th time bin for centre strip", 1100, -99, 1000, "recHits");
1983  }
1984 
1985  for (CSCSegmentCollection::const_iterator it = cscSegments->begin(); it != cscSegments->end(); it++) {
1986  std::vector<CSCRecHit2D> theseRecHits = (*it).specificRecHits();
1987  for (std::vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1988  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
1989  LocalPoint lpRH = (*iRH).localPosition();
1990  float xrec = lpRH.x();
1991  float yrec = lpRH.y();
1992  float zrec = lpRH.z();
1993  bool RHalreadyinMap = false;
1994  //Store the rechits associated with segments into a Map
1995  multimap<CSCDetId, CSCRecHit2D>::iterator segRHit;
1996  segRHit = SegRechits.find(idRH);
1997  if (segRHit != SegRechits.end()) {
1998  for (; segRHit != SegRechits.upper_bound(idRH); ++segRHit) {
1999  //for( segRHit = SegRechits.begin(); segRHit != SegRechits.end() ;++segRHit){
2000  LocalPoint lposRH = (segRHit->second).localPosition();
2001  float xpos = lposRH.x();
2002  float ypos = lposRH.y();
2003  float zpos = lposRH.z();
2004  if (xrec == xpos && yrec == ypos && zrec == zpos) {
2005  RHalreadyinMap = true;
2006  //std::cout << " Already exists " <<std ::endl;
2007  break;
2008  }
2009  }
2010  }
2011  if (!RHalreadyinMap) {
2012  SegRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idRH, *iRH));
2013  }
2014  }
2015  }
2016 
2017  findNonAssociatedRecHits(cscGeom, strips);
2018 }

References dtChamberEfficiency_cfi::cscSegments, combine::histos, FastTrackerRecHitMaskProducer_cfi::recHits, DigiDM_cff::strips, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

◆ doOccupancies()

void CSCValidation::doOccupancies ( edm::Handle< CSCStripDigiCollection strips,
edm::Handle< CSCWireDigiCollection wires,
edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments 
)
private

Definition at line 418 of file CSCValidation.cc.

421  {
422  bool wireo[2][4][4][36];
423  bool stripo[2][4][4][36];
424  bool rechito[2][4][4][36];
425  bool segmento[2][4][4][36];
426 
427  bool hasWires = false;
428  bool hasStrips = false;
429  bool hasRecHits = false;
430  bool hasSegments = false;
431 
432  for (int e = 0; e < 2; e++) {
433  for (int s = 0; s < 4; s++) {
434  for (int r = 0; r < 4; r++) {
435  for (int c = 0; c < 36; c++) {
436  wireo[e][s][r][c] = false;
437  stripo[e][s][r][c] = false;
438  rechito[e][s][r][c] = false;
439  segmento[e][s][r][c] = false;
440  }
441  }
442  }
443  }
444 
445  if (useDigis) {
446  //wires
447  for (CSCWireDigiCollection::DigiRangeIterator wi = wires->begin(); wi != wires->end(); wi++) {
448  CSCDetId id = (CSCDetId)(*wi).first;
449  int kEndcap = id.endcap();
450  int kRing = id.ring();
451  int kStation = id.station();
452  int kChamber = id.chamber();
453  std::vector<CSCWireDigi>::const_iterator wireIt = (*wi).second.first;
454  std::vector<CSCWireDigi>::const_iterator lastWire = (*wi).second.second;
455  for (; wireIt != lastWire; ++wireIt) {
456  if (!wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
457  wireo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
458  hOWires->Fill(kChamber, typeIndex(id));
460  chamberSerial(id), "hOWireSerial", "Wire Occupancy by Chamber Serial", 601, -0.5, 600.5, "Digis");
461  hasWires = true;
462  }
463  }
464  }
465 
466  //strips
467  for (CSCStripDigiCollection::DigiRangeIterator si = strips->begin(); si != strips->end(); si++) {
468  CSCDetId id = (CSCDetId)(*si).first;
469  int kEndcap = id.endcap();
470  int kRing = id.ring();
471  int kStation = id.station();
472  int kChamber = id.chamber();
473  std::vector<CSCStripDigi>::const_iterator stripIt = (*si).second.first;
474  std::vector<CSCStripDigi>::const_iterator lastStrip = (*si).second.second;
475  for (; stripIt != lastStrip; ++stripIt) {
476  std::vector<int> myADCVals = stripIt->getADCCounts();
477  bool thisStripFired = false;
478  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
479  float threshold = 13.3;
480  float diff = 0.;
481  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
482  diff = (float)myADCVals[iCount] - thisPedestal;
483  if (diff > threshold) {
484  thisStripFired = true;
485  }
486  }
487  if (thisStripFired) {
488  if (!stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
489  stripo[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
490  hOStrips->Fill(kChamber, typeIndex(id));
492  chamberSerial(id), "hOStripSerial", "Strip Occupancy by Chamber Serial", 601, -0.5, 600.5, "Digis");
493  hasStrips = true;
494  }
495  }
496  }
497  }
498  }
499 
500  //rechits
502  for (recIt = recHits->begin(); recIt != recHits->end(); recIt++) {
503  CSCDetId idrec = (CSCDetId)(*recIt).cscDetId();
504  int kEndcap = idrec.endcap();
505  int kRing = idrec.ring();
506  int kStation = idrec.station();
507  int kChamber = idrec.chamber();
508  if (!rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
509  rechito[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
511  chamberSerial(idrec), "hORecHitsSerial", "RecHit Occupancy by Chamber Serial", 601, -0.5, 600.5, "recHits");
512  hORecHits->Fill(kChamber, typeIndex(idrec));
513  hasRecHits = true;
514  }
515  }
516 
517  //segments
518  for (CSCSegmentCollection::const_iterator segIt = cscSegments->begin(); segIt != cscSegments->end(); segIt++) {
519  CSCDetId id = (CSCDetId)(*segIt).cscDetId();
520  int kEndcap = id.endcap();
521  int kRing = id.ring();
522  int kStation = id.station();
523  int kChamber = id.chamber();
524  if (!segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1]) {
525  segmento[kEndcap - 1][kStation - 1][kRing - 1][kChamber - 1] = true;
527  chamberSerial(id), "hOSegmentsSerial", "Segment Occupancy by Chamber Serial", 601, -0.5, 600.5, "Segments");
528  hOSegments->Fill(kChamber, typeIndex(id));
529  hasSegments = true;
530  }
531  }
532 
533  // overall CSC occupancy (events with CSC data compared to total)
534  histos->fill1DHist(1, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
535  if (hasWires)
536  histos->fill1DHist(3, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
537  if (hasStrips)
538  histos->fill1DHist(5, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
539  if (hasWires && hasStrips)
540  histos->fill1DHist(7, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
541  if (hasRecHits)
542  histos->fill1DHist(9, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
543  if (hasSegments)
544  histos->fill1DHist(11, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
545  if (!cleanEvent)
546  histos->fill1DHist(13, "hCSCOccupancy", "overall CSC occupancy", 15, -0.5, 14.5, "GeneralHists");
547 }

References c, CSCDetId::chamber(), dtChamberEfficiency_cfi::cscSegments, change_name::diff, MillePedeFileConverter_cfg::e, CSCDetId::endcap(), dqmMemoryStats::float, combine::histos, alignCSCRings::r, FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), alignCSCRings::s, CSCDetId::station(), DigiDM_cff::strips, remoteMonitoring_LED_IterMethod_cfg::threshold, and DigiDM_cff::wires.

◆ doPedestalNoise()

void CSCValidation::doPedestalNoise ( edm::Handle< CSCStripDigiCollection strips)
private

Definition at line 853 of file CSCValidation.cc.

853  {
854  constexpr float threshold = 13.3;
855  for (CSCStripDigiCollection::DigiRangeIterator dPNiter = strips->begin(); dPNiter != strips->end(); dPNiter++) {
856  CSCDetId id = (CSCDetId)(*dPNiter).first;
857  std::vector<CSCStripDigi>::const_iterator pedIt = (*dPNiter).second.first;
858  std::vector<CSCStripDigi>::const_iterator lStrip = (*dPNiter).second.second;
859  for (; pedIt != lStrip; ++pedIt) {
860  int myStrip = pedIt->getStrip();
861  std::vector<int> myADCVals = pedIt->getADCCounts();
862  float TotalADC = getSignal(*strips, id, myStrip);
863  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
864  float thisSignal =
865  (1. / 6) * (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
866  bool thisStripFired = TotalADC > threshold;
867  if (!thisStripFired) {
868  float ADC = thisSignal - thisPedestal;
869  histos->fill1DHist(ADC, "hStripPed", "Pedestal Noise Distribution", 50, -25., 25., "PedestalNoise");
870  histos->fill1DHistByType(ADC, "hStripPedME", "Pedestal Noise Distribution", id, 50, -25., 25., "PedestalNoise");
872  ADC,
873  "hStripPedMEProfile",
874  "Wire TimeBin Fired",
875  601,
876  -0.5,
877  600.5,
878  -25,
879  25,
880  "PedestalNoise");
881  if (detailedAnalysis) {
883  ADC, "hStripPedME", "Pedestal Noise Distribution", id, 50, -25., 25., "PedestalNoiseByLayer");
884  }
885  }
886  }
887  }
888 }

References dtNoiseAnalysis_cfi::detailedAnalysis, dqmMemoryStats::float, cms::cuda::for(), combine::histos, DigiDM_cff::strips, and remoteMonitoring_LED_IterMethod_cfg::threshold.

◆ doRecHits()

void CSCValidation::doRecHits ( edm::Handle< CSCRecHit2DCollection recHits,
edm::ESHandle< CSCGeometry cscGeom 
)
private

Definition at line 896 of file CSCValidation.cc.

896  {
897  // Get the RecHits collection :
898  int nRecHits = recHits->size();
899 
900  // ---------------------
901  // Loop over rechits
902  // ---------------------
903  int iHit = 0;
904 
905  // Build iterator for rechits and loop :
907  for (dRHIter = recHits->begin(); dRHIter != recHits->end(); dRHIter++) {
908  iHit++;
909 
910  // Find chamber with rechits in CSC
911  CSCDetId idrec = (CSCDetId)(*dRHIter).cscDetId();
912  int kEndcap = idrec.endcap();
913  int kRing = idrec.ring();
914  int kStation = idrec.station();
915  int kChamber = idrec.chamber();
916  int kLayer = idrec.layer();
917 
918  // Store rechit as a Local Point:
919  LocalPoint rhitlocal = (*dRHIter).localPosition();
920  float xreco = rhitlocal.x();
921  float yreco = rhitlocal.y();
922  LocalError rerrlocal = (*dRHIter).localPositionError();
923  //these errors are squared!
924  float xxerr = rerrlocal.xx();
925  float yyerr = rerrlocal.yy();
926  float xyerr = rerrlocal.xy();
927  // errors in strip units
928  float stpos = (*dRHIter).positionWithinStrip();
929  float sterr = (*dRHIter).errorWithinStrip();
930 
931  // Find the charge associated with this hit
932  float rHSumQ = 0;
933  float sumsides = 0.;
934  int adcsize = dRHIter->nStrips() * dRHIter->nTimeBins();
935  for (unsigned int i = 0; i < dRHIter->nStrips(); i++) {
936  for (unsigned int j = 0; j < dRHIter->nTimeBins() - 1; j++) {
937  rHSumQ += dRHIter->adcs(i, j);
938  if (i != 1)
939  sumsides += dRHIter->adcs(i, j);
940  }
941  }
942 
943  float rHratioQ = sumsides / rHSumQ;
944  if (adcsize != 12)
945  rHratioQ = -99;
946 
947  // Get the signal timing of this hit
948  float rHtime = 0;
949  rHtime = (*dRHIter).tpeak() / 50.;
950 
951  // Get pointer to the layer:
952  const CSCLayer* csclayer = cscGeom->layer(idrec);
953 
954  // Transform hit position from local chamber geometry to global CMS geom
955  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
956  float grecx = rhitglobal.x();
957  float grecy = rhitglobal.y();
958 
959  // Fill the rechit position branch
960  if (writeTreeToFile && rhTreeCount < 1500000) {
961  histos->fillRechitTree(xreco, yreco, grecx, grecy, kEndcap, kStation, kRing, kChamber, kLayer);
962  rhTreeCount++;
963  }
964 
965  // Fill some histograms
966  // only fill if 3 strips were used in the hit
968  grecx, grecy, "hRHGlobal", "recHit Global Position", idrec, 100, -800., 800., 100, -800., 800., "recHits");
969  if (kStation == 1 && (kRing == 1 || kRing == 4))
970  histos->fill1DHistByType(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 4000, "recHits");
971  else
972  histos->fill1DHistByType(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 2000, "recHits");
973  histos->fill1DHistByType(rHratioQ, "hRHRatioQ", "Charge Ratio (Ql+Qr)/Qt", idrec, 120, -0.1, 1.1, "recHits");
974  histos->fill1DHistByType(rHtime, "hRHTiming", "recHit Timing", idrec, 200, -10, 10, "recHits");
975  histos->fill1DHistByType(sqrt(xxerr), "hRHxerr", "RecHit Error on Local X", idrec, 100, -0.1, 2, "recHits");
976  histos->fill1DHistByType(sqrt(yyerr), "hRHyerr", "RecHit Error on Local Y", idrec, 100, -0.1, 2, "recHits");
977  histos->fill1DHistByType(xyerr, "hRHxyerr", "Corr. RecHit XY Error", idrec, 100, -1, 2, "recHits");
978  if (adcsize == 12)
979  histos->fill1DHistByType(stpos, "hRHstpos", "Reconstructed Position on Strip", idrec, 120, -0.6, 0.6, "recHits");
981  sterr, "hRHsterr", "Estimated Error on Strip Measurement", idrec, 120, -0.05, 0.25, "recHits");
983  chamberSerial(idrec), rHSumQ, "hRHSumQProfile", "Sum 3x3 recHit Charge", 601, -0.5, 600.5, 0, 4000, "recHits");
985  chamberSerial(idrec), rHtime, "hRHTimingProfile", "recHit Timing", 601, -0.5, 600.5, -11, 11, "recHits");
986  if (detailedAnalysis) {
987  if (kStation == 1 && (kRing == 1 || kRing == 4))
988  histos->fill1DHistByLayer(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 4000, "RHQByLayer");
989  else
990  histos->fill1DHistByLayer(rHSumQ, "hRHSumQ", "Sum 3x3 recHit Charge", idrec, 125, 0, 2000, "RHQByLayer");
991  histos->fill1DHistByLayer(rHratioQ, "hRHRatioQ", "Charge Ratio (Ql+Qr)/Qt", idrec, 120, -0.1, 1.1, "RHQByLayer");
992  histos->fill1DHistByLayer(rHtime, "hRHTiming", "recHit Timing", idrec, 200, -10, 10, "RHTimingByLayer");
993  histos->fill2DHistByLayer(xreco,
994  yreco,
995  "hRHLocalXY",
996  "recHit Local Position",
997  idrec,
998  50,
999  -100.,
1000  100.,
1001  75,
1002  -150.,
1003  150.,
1004  "RHLocalXYByLayer");
1006  sqrt(xxerr), "hRHxerr", "RecHit Error on Local X", idrec, 100, -0.1, 2, "RHErrorsByLayer");
1008  sqrt(yyerr), "hRHyerr", "RecHit Error on Local Y", idrec, 100, -0.1, 2, "RHErrorsByLayer");
1010  stpos, "hRHstpos", "Reconstructed Position on Strip", idrec, 120, -0.6, 0.6, "RHStripPosByLayer");
1012  sterr, "hRHsterr", "Estimated Error on Strip Measurement", idrec, 120, -0.05, 0.25, "RHStripPosByLayer");
1013  }
1014 
1015  } //end rechit loop
1016 
1017  if (nRecHits == 0)
1018  nRecHits = -1;
1019 
1020  histos->fill1DHist(nRecHits, "hRHnrechits", "recHits per Event (all chambers)", 151, -0.5, 150.5, "recHits");
1021 }

References CSCDetId::chamber(), dtNoiseAnalysis_cfi::detailedAnalysis, CSCDetId::endcap(), combine::histos, mps_fire::i, dqmiolumiharvest::j, kLayer(), CSCDetId::layer(), CSCGeometry::layer(), FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), mathSSE::sqrt(), CSCDetId::station(), GeomDet::toGlobal(), PV3DBase< T, PVType, FrameType >::x(), LocalError::xx(), LocalError::xy(), PV3DBase< T, PVType, FrameType >::y(), and LocalError::yy().

◆ doResolution()

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

Definition at line 1175 of file CSCValidation.cc.

1175  {
1176  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1177  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1178 
1179  //
1180  // try to get the CSC recHits that contribute to this segment.
1181  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
1182  int nRH = (*dSiter).nRecHits();
1183  int jRH = 0;
1184  CLHEP::HepMatrix sp(6, 1);
1185  CLHEP::HepMatrix se(6, 1);
1186  for (std::vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
1187  jRH++;
1188  CSCDetId idRH = (CSCDetId)(*iRH).cscDetId();
1189  int kRing = idRH.ring();
1190  int kStation = idRH.station();
1191  int kLayer = idRH.layer();
1192 
1193  // Find the strip containing this hit
1194  int centerid = iRH->nStrips() / 2;
1195  int centerStrip = iRH->channels(centerid);
1196 
1197  // If this segment has 6 hits, find the position of each hit on the strip in units of stripwidth and store values
1198  if (nRH == 6) {
1199  float stpos = (*iRH).positionWithinStrip();
1200  se(kLayer, 1) = (*iRH).errorWithinStrip();
1201  // Take into account half-strip staggering of layers (ME1/1 has no staggering)
1202  if (kStation == 1 && (kRing == 1 || kRing == 4))
1203  sp(kLayer, 1) = stpos + centerStrip;
1204  else {
1205  if (kLayer == 1 || kLayer == 3 || kLayer == 5)
1206  sp(kLayer, 1) = stpos + centerStrip;
1207  if (kLayer == 2 || kLayer == 4 || kLayer == 6)
1208  sp(kLayer, 1) = stpos - 0.5 + centerStrip;
1209  }
1210  }
1211  }
1212 
1213  float residual = -99;
1214  float pull = -99;
1215  // Fit all points except layer 3, then compare expected value for layer 3 to reconstructed value
1216  if (nRH == 6) {
1217  float expected = fitX(sp, se);
1218  residual = expected - sp(3, 1);
1219  pull = residual / se(3, 1);
1220  }
1221 
1222  // Fill histos
1224  residual, "hSResid", "Fitted Position on Strip - Reconstructed for Layer 3", id, 100, -0.5, 0.5, "Resolution");
1225  histos->fill1DHistByType(pull, "hSStripPosPull", "Strip Measurement Pulls", id, 100, -5.0, 5.0, "Resolution");
1227  residual,
1228  "hSResidProfile",
1229  "Fitted Position on Strip - Reconstructed for Layer 3",
1230  601,
1231  -0.5,
1232  600.5,
1233  -0.5,
1234  0.5,
1235  "Resolution");
1236  if (detailedAnalysis) {
1237  histos->fill1DHistByChamber(residual,
1238  "hSResid",
1239  "Fitted Position on Strip - Reconstructed for Layer 3",
1240  id,
1241  100,
1242  -0.5,
1243  0.5,
1244  "DetailedResolution");
1245  histos->fill1DHistByChamber(pull, "hSStripPosPull", "Strip Measurement Pulls", id, 100, -5.0, 5.0, "Resolution");
1246  }
1247  }
1248 }

References dtChamberEfficiency_cfi::cscSegments, dtNoiseAnalysis_cfi::detailedAnalysis, combine::histos, kLayer(), CSCDetId::layer(), CSCDetId::ring(), and CSCDetId::station().

◆ doSegments()

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

Definition at line 1081 of file CSCValidation.cc.

1081  {
1082  // get CSC segment collection
1083  int nSegments = cscSegments->size();
1084 
1085  // -----------------------
1086  // loop over segments
1087  // -----------------------
1088  int iSegment = 0;
1089  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
1090  iSegment++;
1091  //
1092  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
1093  int kEndcap = id.endcap();
1094  int kRing = id.ring();
1095  int kStation = id.station();
1096  int kChamber = id.chamber();
1097 
1098  //
1099  float chisq = (*dSiter).chi2();
1100  int nhits = (*dSiter).nRecHits();
1101  int nDOF = 2 * nhits - 4;
1102  double chisqProb = ChiSquaredProbability((double)chisq, nDOF);
1103  LocalPoint localPos = (*dSiter).localPosition();
1104  float segX = localPos.x();
1105  float segY = localPos.y();
1106  LocalVector segDir = (*dSiter).localDirection();
1107  double theta = segDir.theta();
1108 
1109  // global transformation
1110  float globX = 0.;
1111  float globY = 0.;
1112  float globTheta = 0.;
1113  float globPhi = 0.;
1114  const CSCChamber* cscchamber = cscGeom->chamber(id);
1115  if (cscchamber) {
1116  GlobalPoint globalPosition = cscchamber->toGlobal(localPos);
1117  globX = globalPosition.x();
1118  globY = globalPosition.y();
1119  GlobalVector globalDirection = cscchamber->toGlobal(segDir);
1120  globTheta = globalDirection.theta();
1121  globPhi = globalDirection.phi();
1122  }
1123 
1124  // Fill segment position branch
1125  if (writeTreeToFile && segTreeCount < 1500000) {
1126  histos->fillSegmentTree(segX, segY, globX, globY, kEndcap, kStation, kRing, kChamber);
1127  segTreeCount++;
1128  }
1129 
1130  // Fill histos
1131  histos->fill2DHistByStation(globX,
1132  globY,
1133  "hSGlobal",
1134  "Segment Global Positions;global x (cm)",
1135  id,
1136  100,
1137  -800.,
1138  800.,
1139  100,
1140  -800.,
1141  800.,
1142  "Segments");
1143  histos->fill1DHistByType(nhits, "hSnHits", "N hits on Segments", id, 8, -0.5, 7.5, "Segments");
1144  histos->fill1DHistByType(theta, "hSTheta", "local theta segments", id, 128, -3.2, 3.2, "Segments");
1145  histos->fill1DHistByType((chisq / nDOF), "hSChiSq", "segments chi-squared/ndof", id, 110, -0.05, 10.5, "Segments");
1147  chisqProb, "hSChiSqProb", "segments chi-squared probability", id, 110, -0.05, 1.05, "Segments");
1148  histos->fill1DHist(globTheta, "hSGlobalTheta", "segment global theta", 128, 0, 3.2, "Segments");
1149  histos->fill1DHist(globPhi, "hSGlobalPhi", "segment global phi", 128, -3.2, 3.2, "Segments");
1151  chamberSerial(id), nhits, "hSnHitsProfile", "N hits on Segments", 601, -0.5, 600.5, -0.5, 7.5, "Segments");
1152  if (detailedAnalysis) {
1153  histos->fill1DHistByChamber(nhits, "hSnHits", "N hits on Segments", id, 8, -0.5, 7.5, "HitsOnSegmentByChamber");
1154  histos->fill1DHistByChamber(theta, "hSTheta", "local theta segments", id, 128, -3.2, 3.2, "DetailedSegments");
1156  (chisq / nDOF), "hSChiSq", "segments chi-squared/ndof", id, 110, -0.05, 10.5, "SegChi2ByChamber");
1158  chisqProb, "hSChiSqProb", "segments chi-squared probability", id, 110, -0.05, 1.05, "SegChi2ByChamber");
1159  }
1160 
1161  } // end segment loop
1162 
1163  if (nSegments == 0)
1164  nSegments = -1;
1165 
1166  histos->fill1DHist(nSegments, "hSnSegments", "Segments per Event", 31, -0.5, 30.5, "Segments");
1167 }

References CSCGeometry::chamber(), ChiSquaredProbability(), dtChamberEfficiency_cfi::cscSegments, dtNoiseAnalysis_cfi::detailedAnalysis, CSCDetId::endcap(), combine::histos, nhits, PV3DBase< T, PVType, FrameType >::phi(), PV3DBase< T, PVType, FrameType >::theta(), theta(), GeomDet::toGlobal(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

◆ doSimHits()

void CSCValidation::doSimHits ( edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< edm::PSimHitContainer simHits 
)
private

Definition at line 1029 of file CSCValidation.cc.

1029  {
1031  for (dSHrecIter = recHits->begin(); dSHrecIter != recHits->end(); dSHrecIter++) {
1032  CSCDetId idrec = (CSCDetId)(*dSHrecIter).cscDetId();
1033  LocalPoint rhitlocal = (*dSHrecIter).localPosition();
1034  float xreco = rhitlocal.x();
1035  float yreco = rhitlocal.y();
1036  float xError = sqrt((*dSHrecIter).localPositionError().xx());
1037  float yError = sqrt((*dSHrecIter).localPositionError().yy());
1038  float simHitXres = -99;
1039  float simHitYres = -99;
1040  float xPull = -99;
1041  float yPull = -99;
1042  float mindiffX = 99;
1043  float mindiffY = 10;
1044  // If MC, find closest muon simHit to check resolution:
1045  PSimHitContainer::const_iterator dSHsimIter;
1046  for (dSHsimIter = simHits->begin(); dSHsimIter != simHits->end(); dSHsimIter++) {
1047  // Get DetID for this simHit:
1048  CSCDetId sId = (CSCDetId)(*dSHsimIter).detUnitId();
1049  // Check if the simHit detID matches that of current recHit
1050  // and make sure it is a muon hit:
1051  if (sId == idrec && abs((*dSHsimIter).particleType()) == 13) {
1052  // Get the position of this simHit in local coordinate system:
1053  LocalPoint sHitlocal = (*dSHsimIter).localPosition();
1054  // Now we need to make reasonably sure that this simHit is
1055  // responsible for this recHit:
1056  if ((sHitlocal.x() - xreco) < mindiffX && (sHitlocal.y() - yreco) < mindiffY) {
1057  simHitXres = (sHitlocal.x() - xreco);
1058  simHitYres = (sHitlocal.y() - yreco);
1059  mindiffX = (sHitlocal.x() - xreco);
1060  xPull = simHitXres / xError;
1061  yPull = simHitYres / yError;
1062  }
1063  }
1064  }
1065 
1067  simHitXres, "hSimXResid", "SimHitX - Reconstructed X", idrec, 100, -1.0, 1.0, "Resolution");
1069  simHitYres, "hSimYResid", "SimHitY - Reconstructed Y", idrec, 100, -5.0, 5.0, "Resolution");
1070  histos->fill1DHistByType(xPull, "hSimXPull", "Local X Pulls", idrec, 100, -5.0, 5.0, "Resolution");
1071  histos->fill1DHistByType(yPull, "hSimYPull", "Local Y Pulls", idrec, 100, -5.0, 5.0, "Resolution");
1072  }
1073 }

References funct::abs(), combine::histos, FastTrackerRecHitMaskProducer_cfi::recHits, FastTrackerRecHitCombiner_cfi::simHits, mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

◆ doStandalone()

void CSCValidation::doStandalone ( edm::Handle< reco::TrackCollection saMuons)
private

Definition at line 1256 of file CSCValidation.cc.

1256  {
1257  int nSAMuons = saMuons->size();
1258  histos->fill1DHist(nSAMuons, "trNSAMuons", "N Standalone Muons per Event", 6, -0.5, 5.5, "STAMuons");
1259 
1260  for (reco::TrackCollection::const_iterator muon = saMuons->begin(); muon != saMuons->end(); ++muon) {
1261  float preco = muon->p();
1262  float ptreco = muon->pt();
1263  int n = muon->recHitsSize();
1264  float chi2 = muon->chi2();
1265  float normchi2 = muon->normalizedChi2();
1266 
1267  // loop over hits
1268  int nDTHits = 0;
1269  int nCSCHits = 0;
1270  int nCSCHitsp = 0;
1271  int nCSCHitsm = 0;
1272  int nRPCHits = 0;
1273  int nRPCHitsp = 0;
1274  int nRPCHitsm = 0;
1275  int np = 0;
1276  int nm = 0;
1277  std::vector<CSCDetId> staChambers;
1278  for (trackingRecHit_iterator hit = muon->recHitsBegin(); hit != muon->recHitsEnd(); ++hit) {
1279  const DetId detId((*hit)->geographicalId());
1280  if (detId.det() == DetId::Muon) {
1281  if (detId.subdetId() == MuonSubdetId::RPC) {
1282  RPCDetId rpcId(detId.rawId());
1283  nRPCHits++;
1284  if (rpcId.region() == 1) {
1285  nRPCHitsp++;
1286  np++;
1287  }
1288  if (rpcId.region() == -1) {
1289  nRPCHitsm++;
1290  nm++;
1291  }
1292  }
1293  if (detId.subdetId() == MuonSubdetId::DT) {
1294  nDTHits++;
1295  } else if (detId.subdetId() == MuonSubdetId::CSC) {
1296  CSCDetId cscId(detId.rawId());
1297  staChambers.push_back(detId.rawId());
1298  nCSCHits++;
1299  if (cscId.endcap() == 1) {
1300  nCSCHitsp++;
1301  np++;
1302  }
1303  if (cscId.endcap() == 2) {
1304  nCSCHitsm++;
1305  nm++;
1306  }
1307  }
1308  }
1309  }
1310 
1311  GlobalPoint innerPnt(muon->innerPosition().x(), muon->innerPosition().y(), muon->innerPosition().z());
1312  GlobalPoint outerPnt(muon->outerPosition().x(), muon->outerPosition().y(), muon->outerPosition().z());
1313  GlobalVector innerKin(muon->innerMomentum().x(), muon->innerMomentum().y(), muon->innerMomentum().z());
1314  GlobalVector outerKin(muon->outerMomentum().x(), muon->outerMomentum().y(), muon->outerMomentum().z());
1315  GlobalVector deltaPnt = innerPnt - outerPnt;
1316  double crudeLength = deltaPnt.mag();
1317  double deltaPhi = innerPnt.phi() - outerPnt.phi();
1318  double innerGlobalPolarAngle = innerKin.theta();
1319  double outerGlobalPolarAngle = outerKin.theta();
1320 
1321  // fill histograms
1322  histos->fill1DHist(n, "trN", "N hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1323  if (np != 0)
1324  histos->fill1DHist(np, "trNp", "N hits on a STA Muon Track (plus endcap)", 51, -0.5, 50.5, "STAMuons");
1325  if (nm != 0)
1326  histos->fill1DHist(nm, "trNm", "N hits on a STA Muon Track (minus endcap)", 51, -0.5, 50.5, "STAMuons");
1327  histos->fill1DHist(nDTHits, "trNDT", "N DT hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1328  histos->fill1DHist(nCSCHits, "trNCSC", "N CSC hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1329  if (nCSCHitsp != 0)
1330  histos->fill1DHist(nCSCHitsp, "trNCSCp", "N CSC hits on a STA Muon Track (+ endcap)", 51, -0.5, 50.5, "STAMuons");
1331  if (nCSCHitsm != 0)
1332  histos->fill1DHist(nCSCHitsm, "trNCSCm", "N CSC hits on a STA Muon Track (- endcap)", 51, -0.5, 50.5, "STAMuons");
1333  histos->fill1DHist(nRPCHits, "trNRPC", "N RPC hits on a STA Muon Track", 51, -0.5, 50.5, "STAMuons");
1334  if (nRPCHitsp != 0)
1335  histos->fill1DHist(nRPCHitsp, "trNRPCp", "N RPC hits on a STA Muon Track (+ endcap)", 51, -0.5, 50.5, "STAMuons");
1336  if (nRPCHitsm != 0)
1337  histos->fill1DHist(nRPCHitsm, "trNRPCm", "N RPC hits on a STA Muon Track (- endcap)", 51, -0.5, 50.5, "STAMuons");
1338  histos->fill1DHist(preco, "trP", "STA Muon Momentum", 100, 0, 300, "STAMuons");
1339  histos->fill1DHist(ptreco, "trPT", "STA Muon pT", 100, 0, 40, "STAMuons");
1340  histos->fill1DHist(chi2, "trChi2", "STA Muon Chi2", 100, 0, 200, "STAMuons");
1341  histos->fill1DHist(normchi2, "trNormChi2", "STA Muon Normalized Chi2", 100, 0, 10, "STAMuons");
1342  histos->fill1DHist(crudeLength, "trLength", "Straight Line Length of STA Muon", 120, 0., 2400., "STAMuons");
1343  histos->fill1DHist(
1344  deltaPhi, "trDeltaPhi", "Delta-Phi Between Inner and Outer STA Muon Pos.", 100, -0.5, 0.5, "STAMuons");
1345  histos->fill1DHist(
1346  innerGlobalPolarAngle, "trInnerPolar", "Polar Angle of Inner P Vector (STA muons)", 128, 0, 3.2, "STAMuons");
1347  histos->fill1DHist(
1348  outerGlobalPolarAngle, "trOuterPolar", "Polar Angle of Outer P Vector (STA muons)", 128, 0, 3.2, "STAMuons");
1349  histos->fill1DHist(innerPnt.phi(), "trInnerPhi", "Phi of Inner Position (STA muons)", 256, -3.2, 3.2, "STAMuons");
1350  histos->fill1DHist(outerPnt.phi(), "trOuterPhi", "Phi of Outer Position (STA muons)", 256, -3.2, 3.2, "STAMuons");
1351  }
1352 }

References hltPixelTracks_cff::chi2, MuonSubdetId::CSC, SiPixelRawToDigiRegional_cfi::deltaPhi, MuonSubdetId::DT, combine::histos, PV3DBase< T, PVType, FrameType >::mag(), DetId::Muon, HLT_FULL_cff::muon, dqmiodumpmetadata::n, np, and MuonSubdetId::RPC.

◆ doStripDigis()

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

Definition at line 811 of file CSCValidation.cc.

811  {
812  int nStripsFired = 0;
813  for (CSCStripDigiCollection::DigiRangeIterator dSDiter = strips->begin(); dSDiter != strips->end(); dSDiter++) {
814  CSCDetId id = (CSCDetId)(*dSDiter).first;
815  std::vector<CSCStripDigi>::const_iterator stripIter = (*dSDiter).second.first;
816  std::vector<CSCStripDigi>::const_iterator lStrip = (*dSDiter).second.second;
817  for (; stripIter != lStrip; ++stripIter) {
818  int myStrip = stripIter->getStrip();
819  std::vector<int> myADCVals = stripIter->getADCCounts();
820  bool thisStripFired = false;
821  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
822  float threshold = 13.3;
823  float diff = 0.;
824  for (unsigned int iCount = 0; iCount < myADCVals.size(); iCount++) {
825  diff = (float)myADCVals[iCount] - thisPedestal;
826  if (diff > threshold) {
827  thisStripFired = true;
828  }
829  }
830  if (thisStripFired) {
831  nStripsFired++;
832  // fill strip histos
833  histos->fill1DHistByType(myStrip, "hStripStrip", "Strip Number", id, 81, -0.5, 80.5, "Digis");
834  if (detailedAnalysis) {
835  histos->fill1DHistByLayer(myStrip, "hStripStrip", "Strip Number", id, 81, -0.5, 80.5, "StripNumberByLayer");
836  }
837  }
838  }
839  } // end strip loop
840 
841  if (nStripsFired == 0)
842  nStripsFired = -1;
843 
844  histos->fill1DHist(nStripsFired, "hStripNFired", "Fired Strips per Event", 251, -0.5, 250.5, "Digis");
845 }

References dtNoiseAnalysis_cfi::detailedAnalysis, change_name::diff, dqmMemoryStats::float, cms::cuda::for(), combine::histos, DigiDM_cff::strips, and remoteMonitoring_LED_IterMethod_cfg::threshold.

◆ doTimeMonitoring()

void CSCValidation::doTimeMonitoring ( edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments,
edm::Handle< CSCALCTDigiCollection alcts,
edm::Handle< CSCCLCTDigiCollection clcts,
edm::Handle< CSCCorrelatedLCTDigiCollection correlatedlcts,
edm::Handle< L1MuGMTReadoutCollection pCollection,
edm::ESHandle< CSCGeometry cscGeom,
const edm::EventSetup eventSetup,
const edm::Event event 
)
private

Get a handle to the FED data collection

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

examine event for integrity

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

adjust crate numbers for MTCC data

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 2933 of file CSCValidation.cc.

2941  {
2942  map<CSCDetId, float> segment_median_map; //structure for storing the median time for segments in a chamber
2943  map<CSCDetId, GlobalPoint> segment_position_map; //structure for storing the global position for segments in a chamber
2944 
2945  // -----------------------
2946  // loop over segments
2947  // -----------------------
2948  int iSegment = 0;
2949  for (CSCSegmentCollection::const_iterator dSiter = cscSegments->begin(); dSiter != cscSegments->end(); dSiter++) {
2950  iSegment++;
2951 
2952  CSCDetId id = (CSCDetId)(*dSiter).cscDetId();
2953  LocalPoint localPos = (*dSiter).localPosition();
2954  GlobalPoint globalPosition = GlobalPoint(0.0, 0.0, 0.0);
2955  const CSCChamber* cscchamber = cscGeom->chamber(id);
2956  if (cscchamber) {
2957  globalPosition = cscchamber->toGlobal(localPos);
2958  }
2959 
2960  // try to get the CSC recHits that contribute to this segment.
2961  std::vector<CSCRecHit2D> theseRecHits = (*dSiter).specificRecHits();
2962  int nRH = (*dSiter).nRecHits();
2963  if (nRH < 4)
2964  continue;
2965 
2966  //Store the recHit times of a segment in a vector for later sorting
2967  vector<float> non_zero;
2968 
2969  for (vector<CSCRecHit2D>::const_iterator iRH = theseRecHits.begin(); iRH != theseRecHits.end(); iRH++) {
2970  non_zero.push_back(iRH->tpeak());
2971 
2972  } // end rechit loop
2973 
2974  //Sort the vector of hit times for this segment and average the center two
2975  sort(non_zero.begin(), non_zero.end());
2976  int middle_index = non_zero.size() / 2;
2977  float average_two = (non_zero.at(middle_index - 1) + non_zero.at(middle_index)) / 2.;
2978  if (non_zero.size() % 2)
2979  average_two = non_zero.at(middle_index);
2980 
2981  //If we've vetoed events with multiple segments per chamber, this should never overwrite informations
2982  segment_median_map[id] = average_two;
2983  segment_position_map[id] = globalPosition;
2984 
2985  double distToIP = sqrt(globalPosition.x() * globalPosition.x() + globalPosition.y() * globalPosition.y() +
2986  globalPosition.z() * globalPosition.z());
2987 
2989  average_two,
2990  "timeChamber",
2991  "Segment mean time",
2992  601,
2993  -0.5,
2994  600.5,
2995  -400.,
2996  400.,
2997  "TimeMonitoring");
2999  average_two,
3000  "timeChamberByType",
3001  "Segment mean time by chamber",
3002  id,
3003  36,
3004  0.5,
3005  36.5,
3006  -400,
3007  400.,
3008  "TimeMonitoring");
3009  histos->fill2DHist(distToIP,
3010  average_two,
3011  "seg_time_vs_distToIP",
3012  "Segment time vs. Distance to IP",
3013  80,
3014  600.,
3015  1400.,
3016  800,
3017  -400,
3018  400.,
3019  "TimeMonitoring");
3020  histos->fill2DHist(globalPosition.z(),
3021  average_two,
3022  "seg_time_vs_globZ",
3023  "Segment time vs. z position",
3024  240,
3025  -1200,
3026  1200,
3027  800,
3028  -400.,
3029  400.,
3030  "TimeMonitoring");
3031  histos->fill2DHist(fabs(globalPosition.z()),
3032  average_two,
3033  "seg_time_vs_absglobZ",
3034  "Segment time vs. abs(z position)",
3035  120,
3036  0.,
3037  1200.,
3038  800,
3039  -400.,
3040  400.,
3041  "TimeMonitoring");
3042 
3043  } //end segment loop
3044 
3045  //Now that the information for each segment we're interest in is stored, it is time to go through the pairs and make plots
3046  map<CSCDetId, float>::const_iterator it_outer; //for the outer loop
3047  map<CSCDetId, float>::const_iterator it_inner; //for the nested inner loop
3048  for (it_outer = segment_median_map.begin(); it_outer != segment_median_map.end(); it_outer++) {
3049  CSCDetId id_outer = it_outer->first;
3050  float t_outer = it_outer->second;
3051 
3052  //begin the inner loop
3053  for (it_inner = segment_median_map.begin(); it_inner != segment_median_map.end(); it_inner++) {
3054  CSCDetId id_inner = it_inner->first;
3055  float t_inner = it_inner->second;
3056 
3057  // we're looking at ordered pairs, so combinations will be double counted
3058  // (chamber a, chamber b) will be counted as well as (chamber b, chamber a)
3059  // We will avoid (chamber a, chamber a) with the following line
3060  if (chamberSerial(id_outer) == chamberSerial(id_inner))
3061  continue;
3062 
3063  // Calculate expected TOF (in ns units)
3064  // GlobalPoint gp_outer = segment_position_map.find(id_outer)->second;
3065  // GlobalPoint gp_inner = segment_position_map.find(id_inner)->second;
3066  // GlobalVector flight = gp_outer - gp_inner; //in cm
3067  // float TOF = flight.mag()/30.0; //to ns
3068 
3069  //Plot t(ME+) - t(ME-) for chamber pairs in the same stations and rings but opposite endcaps
3070  if (id_outer.endcap() == 1 && id_inner.endcap() == 2 && id_outer.station() == id_inner.station() &&
3071  id_outer.ring() == id_inner.ring()) {
3072  histos->fill1DHist(t_outer - t_inner,
3073  "diff_opposite_endcaps",
3074  "#Delta t [ME+]-[ME-] for chambers in same station and ring",
3075  800,
3076  -400.,
3077  400.,
3078  "TimeMonitoring");
3079  histos->fill1DHistByType(t_outer - t_inner,
3080  "diff_opposite_endcaps_byType",
3081  "#Delta t [ME+]-[ME-] for chambers in same station and ring",
3082  id_outer,
3083  800,
3084  -400.,
3085  400.,
3086  "TimeMonitoring");
3087  }
3088 
3089  } //end inner loop of segment pairs
3090  } //end outer loop of segment pairs
3091 
3092  //if the digis, return here
3093  if (!useDigis)
3094  return;
3095 
3096  //looking for the global trigger number
3097  vector<L1MuGMTReadoutRecord> L1Mrec = pCollection->getRecords();
3098  vector<L1MuGMTReadoutRecord>::const_iterator igmtrr;
3099  int L1GMT_BXN = -100;
3100  bool has_CSCTrigger = false;
3101  bool has_beamHaloTrigger = false;
3102  for (igmtrr = L1Mrec.begin(); igmtrr != L1Mrec.end(); igmtrr++) {
3103  std::vector<L1MuRegionalCand>::const_iterator iter1;
3104  std::vector<L1MuRegionalCand> rmc;
3105  // CSC
3106  int icsc = 0;
3107  rmc = igmtrr->getCSCCands();
3108  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
3109  if (!(*iter1).empty()) {
3110  icsc++;
3111  int kQuality = (*iter1).quality(); // kQuality = 1 means beam halo
3112  if (kQuality == 1)
3113  has_beamHaloTrigger = true;
3114  }
3115  }
3116  if (igmtrr->getBxInEvent() == 0 && icsc > 0) {
3117  //printf("L1 CSCCands exist. L1MuGMTReadoutRecord BXN = %d \n", igmtrr->getBxNr());
3118  L1GMT_BXN = igmtrr->getBxNr();
3119  has_CSCTrigger = true;
3120  } else if (igmtrr->getBxInEvent() == 0) {
3121  //printf("L1 CSCCands do not exist. L1MuGMTReadoutRecord BXN = %d \n", igmtrr->getBxNr());
3122  L1GMT_BXN = igmtrr->getBxNr();
3123  }
3124  }
3125 
3126  // *************************************************
3127  // *** ALCT Digis **********************************
3128  // *************************************************
3129 
3130  int n_alcts = 0;
3131  map<CSCDetId, int> ALCT_KeyWG_map; //structure for storing the key wire group for the first ALCT for each chamber
3132  for (CSCALCTDigiCollection::DigiRangeIterator j = alcts->begin(); j != alcts->end(); j++) {
3133  const CSCALCTDigiCollection::Range& range = (*j).second;
3134  const CSCDetId& idALCT = (*j).first;
3135  for (CSCALCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3136  // Valid digi in the chamber (or in neighbouring chamber)
3137  if ((*digiIt).isValid()) {
3138  n_alcts++;
3139  histos->fill1DHist((*digiIt).getBX(), "ALCT_getBX", "ALCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3140  histos->fill1DHist(
3141  (*digiIt).getFullBX(), "ALCT_getFullBX", "ALCT.getFullBX()", 3601, -0.5, 3600.5, "TimeMonitoring");
3142  //if we don't already have digi information stored for this chamber, then we fill it
3143  if (ALCT_KeyWG_map.find(idALCT.chamberId()) == ALCT_KeyWG_map.end()) {
3144  ALCT_KeyWG_map[idALCT.chamberId()] = (*digiIt).getKeyWG();
3145  //printf("I did fill ALCT info for Chamber %d %d %d %d \n",idALCT.chamberId().endcap(), idALCT.chamberId().station(), idALCT.chamberId().ring(), idALCT.chamberId().chamber());
3146  }
3147  }
3148  }
3149  }
3150 
3151  // *************************************************
3152  // *** CLCT Digis **********************************
3153  // *************************************************
3154  int n_clcts = 0;
3155  map<CSCDetId, int> CLCT_getFullBx_map; //structure for storing the pretrigger bxn for the first CLCT for each chamber
3156  for (CSCCLCTDigiCollection::DigiRangeIterator j = clcts->begin(); j != clcts->end(); j++) {
3157  const CSCCLCTDigiCollection::Range& range = (*j).second;
3158  const CSCDetId& idCLCT = (*j).first;
3159  for (CSCCLCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3160  // Valid digi in the chamber (or in neighbouring chamber)
3161  if ((*digiIt).isValid()) {
3162  n_clcts++;
3163  histos->fill1DHist((*digiIt).getBX(), "CLCT_getBX", "CLCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3164  histos->fill1DHist(
3165  (*digiIt).getFullBX(), "CLCT_getFullBX", "CLCT.getFullBX()", 3601, -0.5, 3600.5, "TimeMonitoring");
3166  //if we don't already have digi information stored for this chamber, then we fill it
3167  if (CLCT_getFullBx_map.find(idCLCT.chamberId()) == CLCT_getFullBx_map.end()) {
3168  CLCT_getFullBx_map[idCLCT.chamberId()] = (*digiIt).getFullBX();
3169  //printf("I did fill CLCT info for Chamber %d %d %d %d \n",idCLCT.chamberId().endcap(), idCLCT.chamberId().station(), idCLCT.chamberId().ring(), idCLCT.chamberId().chamber());
3170  }
3171  }
3172  }
3173  }
3174 
3175  // *************************************************
3176  // *** CorrelatedLCT Digis *************************
3177  // *************************************************
3178  int n_correlatedlcts = 0;
3179  for (CSCCorrelatedLCTDigiCollection::DigiRangeIterator j = correlatedlcts->begin(); j != correlatedlcts->end(); j++) {
3180  const CSCCorrelatedLCTDigiCollection::Range& range = (*j).second;
3181  for (CSCCorrelatedLCTDigiCollection::const_iterator digiIt = range.first; digiIt != range.second; ++digiIt) {
3182  if ((*digiIt).isValid()) {
3183  n_correlatedlcts++;
3184  histos->fill1DHist(
3185  (*digiIt).getBX(), "CorrelatedLCTS_getBX", "CorrelatedLCT.getBX()", 11, -0.5, 10.5, "TimeMonitoring");
3186  }
3187  }
3188  }
3189 
3190  int nRecHits = recHits->size();
3191  int nSegments = cscSegments->size();
3192  if (has_CSCTrigger) {
3193  histos->fill1DHist(L1GMT_BXN, "BX_L1CSCCand", "BX of L1 CSC Cand", 4001, -0.5, 4000.5, "TimeMonitoring");
3194  histos->fill2DHist(L1GMT_BXN,
3195  n_alcts,
3196  "n_ALCTs_v_BX_L1CSCCand",
3197  "Number of ALCTs vs. BX of L1 CSC Cand",
3198  4001,
3199  -0.5,
3200  4000.5,
3201  51,
3202  -0.5,
3203  50.5,
3204  "TimeMonitoring");
3205  histos->fill2DHist(L1GMT_BXN,
3206  n_clcts,
3207  "n_CLCTs_v_BX_L1CSCCand",
3208  "Number of CLCTs vs. BX of L1 CSC Cand",
3209  4001,
3210  -0.5,
3211  4000.5,
3212  51,
3213  -0.5,
3214  50.5,
3215  "TimeMonitoring");
3216  histos->fill2DHist(L1GMT_BXN,
3217  n_correlatedlcts,
3218  "n_CorrelatedLCTs_v_BX_L1CSCCand",
3219  "Number of CorrelatedLCTs vs. BX of L1 CSC Cand",
3220  4001,
3221  -0.5,
3222  4000.5,
3223  51,
3224  -0.5,
3225  50.5,
3226  "TimeMonitoring");
3227  histos->fill2DHist(L1GMT_BXN,
3228  nRecHits,
3229  "n_RecHits_v_BX_L1CSCCand",
3230  "Number of RecHits vs. BX of L1 CSC Cand",
3231  4001,
3232  -0.5,
3233  4000.5,
3234  101,
3235  -0.5,
3236  100.5,
3237  "TimeMonitoring");
3238  histos->fill2DHist(L1GMT_BXN,
3239  nSegments,
3240  "n_Segments_v_BX_L1CSCCand",
3241  "Number of Segments vs. BX of L1 CSC Cand",
3242  4001,
3243  -0.5,
3244  4000.5,
3245  51,
3246  -0.5,
3247  50.5,
3248  "TimeMonitoring");
3249  }
3250  if (has_CSCTrigger && has_beamHaloTrigger) {
3251  histos->fill1DHist(
3252  L1GMT_BXN, "BX_L1CSCCand_w_beamHalo", "BX of L1 CSC (w beamHalo bit)", 4001, -0.5, 4000.5, "TimeMonitoring");
3253  histos->fill2DHist(L1GMT_BXN,
3254  n_alcts,
3255  "n_ALCTs_v_BX_L1CSCCand_w_beamHalo",
3256  "Number of ALCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3257  4001,
3258  -0.5,
3259  4000.5,
3260  51,
3261  -0.5,
3262  50.5,
3263  "TimeMonitoring");
3264  histos->fill2DHist(L1GMT_BXN,
3265  n_clcts,
3266  "n_CLCTs_v_BX_L1CSCCand_w_beamHalo",
3267  "Number of CLCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3268  4001,
3269  -0.5,
3270  4000.5,
3271  51,
3272  -0.5,
3273  50.5,
3274  "TimeMonitoring");
3275  histos->fill2DHist(L1GMT_BXN,
3276  n_correlatedlcts,
3277  "n_CorrelatedLCTs_v_BX_L1CSCCand_w_beamHalo",
3278  "Number of CorrelatedLCTs vs. BX of L1 CSC Cand (w beamHalo bit)",
3279  4001,
3280  -0.5,
3281  4000.5,
3282  51,
3283  -0.5,
3284  50.5,
3285  "TimeMonitoring");
3286  histos->fill2DHist(L1GMT_BXN,
3287  nRecHits,
3288  "n_RecHits_v_BX_L1CSCCand_w_beamHalo",
3289  "Number of RecHits vs. BX of L1 CSC Cand (w beamHalo bit)",
3290  4001,
3291  -0.5,
3292  4000.5,
3293  101,
3294  -0.5,
3295  100.5,
3296  "TimeMonitoring");
3297  histos->fill2DHist(L1GMT_BXN,
3298  nSegments,
3299  "n_Segments_v_BX_L1CSCCand_w_beamHalo",
3300  "Number of Segments vs. BX of L1 CSC Cand (w beamHalo bit)",
3301  4001,
3302  -0.5,
3303  4000.5,
3304  51,
3305  -0.5,
3306  50.5,
3307  "TimeMonitoring");
3308  }
3309 
3310  // *******************************************************************
3311  // Get information from the TMB header.
3312  // Can this eventually come out of the digis?
3313  // Taking code from EventFilter/CSCRawToDigis/CSCDCCUnpacker.cc
3314  // *******************************************************************
3315 
3317  eventSetup.get<CSCCrateMapRcd>().get(hcrate);
3318  const CSCCrateMap* pcrate = hcrate.product();
3319 
3322  event.getByToken(rd_token, rawdata);
3323  // If set selective unpacking mode
3324  // hardcoded examiner mask below to check for DCC and DDU level errors will be used first
3325  // then examinerMask for CSC level errors will be used during unpacking of each CSC block
3326  unsigned long dccBinCheckMask = 0x06080016;
3327  unsigned int examinerMask = 0x1FEBF3F6;
3328  unsigned int errorMask = 0x0;
3329 
3330  for (int id = FEDNumbering::MINCSCFEDID; id <= FEDNumbering::MAXCSCFEDID; ++id) {
3331  // loop over DCCs
3334 
3336  const FEDRawData& fedData = rawdata->FEDData(id);
3337  unsigned long length = fedData.size();
3338 
3339  if (length >= 32) {
3340  std::stringstream examiner_out, examiner_err;
3342  CSCDCCExaminer* examiner = new CSCDCCExaminer();
3343  if (examinerMask & 0x40000)
3344  examiner->crcCFEB(true);
3345  if (examinerMask & 0x8000)
3346  examiner->crcTMB(true);
3347  if (examinerMask & 0x0400)
3348  examiner->crcALCT(true);
3349  examiner->setMask(examinerMask);
3350  const short unsigned int* data = (short unsigned int*)fedData.data();
3351 
3352  bool goodEvent;
3353  if (examiner->check(data, long(fedData.size() / 2)) < 0) {
3354  goodEvent = false;
3355  } else {
3356  goodEvent = !(examiner->errors() & dccBinCheckMask);
3357  }
3358 
3359  if (goodEvent) {
3361  CSCDCCExaminer* ptrExaminer = examiner;
3362  CSCDCCEventData dccData((short unsigned int*)fedData.data(), ptrExaminer);
3363 
3365  const std::vector<CSCDDUEventData>& dduData = dccData.dduData();
3366 
3368  CSCDetId layer(1, 1, 1, 1, 1);
3369 
3370  for (unsigned int iDDU = 0; iDDU < dduData.size(); ++iDDU) { // loop over DDUs
3373  if (dduData[iDDU].trailer().errorstat() & errorMask) {
3374  LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "DDU# " << iDDU << " has serious error - no digis unpacked! "
3375  << std::hex << dduData[iDDU].trailer().errorstat();
3376  continue; // to next iteration of DDU loop
3377  }
3378 
3380  const std::vector<CSCEventData>& cscData = dduData[iDDU].cscData();
3381  for (unsigned int iCSC = 0; iCSC < cscData.size(); ++iCSC) { // loop over CSCs
3382 
3383  int vmecrate = cscData[iCSC].dmbHeader()->crateID();
3384  int dmb = cscData[iCSC].dmbHeader()->dmbID();
3385 
3387  // SKIPPING MTCC redefinition of vmecrate
3388 
3389  int icfeb = 0;
3390  int ilayer = 0;
3391 
3392  if ((vmecrate >= 1) && (vmecrate <= 60) && (dmb >= 1) && (dmb <= 10) && (dmb != 6)) {
3393  layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
3394  } else {
3395  LogTrace("CSCTimingAlignment|CSCDCCUnpacker|CSCRawToDigi") << " detID input out of range!!! ";
3396  LogTrace("CSCTimingAlignment|CSCDCCUnpacker|CSCRawToDigi")
3397  << " skipping chamber vme= " << vmecrate << " dmb= " << dmb;
3398  continue; // to next iteration of iCSC loop
3399  }
3400 
3402  int nalct = cscData[iCSC].dmbHeader()->nalct();
3403  bool goodALCT = false;
3404  //if (nalct&&(cscData[iCSC].dataPresent>>6&0x1)==1) {
3405  if (nalct && cscData[iCSC].alctHeader()) {
3406  if (cscData[iCSC].alctHeader()->check()) {
3407  goodALCT = true;
3408  }
3409  }
3410 
3412  int nclct = cscData[iCSC].dmbHeader()->nclct();
3413  bool goodTMB = false;
3414  if (nclct && cscData[iCSC].tmbData()) {
3415  if (cscData[iCSC].tmbHeader()->check()) {
3416  if (cscData[iCSC].comparatorData()->check())
3417  goodTMB = true;
3418  }
3419  }
3420 
3421  if (goodTMB && goodALCT) {
3422  if (ALCT_KeyWG_map.find(layer) == ALCT_KeyWG_map.end()) {
3423  printf("no ALCT info for Chamber %d %d %d %d \n",
3424  layer.endcap(),
3425  layer.station(),
3426  layer.ring(),
3427  layer.chamber());
3428  continue;
3429  }
3430  if (CLCT_getFullBx_map.find(layer) == CLCT_getFullBx_map.end()) {
3431  printf("no CLCT info for Chamber %d %d %d %d \n",
3432  layer.endcap(),
3433  layer.station(),
3434  layer.ring(),
3435  layer.chamber());
3436  continue;
3437  }
3438  int ALCT0Key = ALCT_KeyWG_map.find(layer)->second;
3439  int CLCTPretrigger = CLCT_getFullBx_map.find(layer)->second;
3440 
3441  const CSCTMBHeader* tmbHead = cscData[iCSC].tmbHeader();
3442 
3443  histos->fill1DHistByStation(tmbHead->BXNCount(),
3444  "TMB_BXNCount",
3445  "TMB_BXNCount",
3446  layer.chamberId(),
3447  3601,
3448  -0.5,
3449  3600.5,
3450  "TimeMonitoring");
3452  "TMB_ALCTMatchTime",
3453  "TMB_ALCTMatchTime",
3454  layer.chamberId(),
3455  7,
3456  -0.5,
3457  6.5,
3458  "TimeMonitoring");
3459 
3460  histos->fill1DHist(
3461  tmbHead->BXNCount(), "TMB_BXNCount", "TMB_BXNCount", 3601, -0.5, 3600.5, "TimeMonitoring");
3462  histos->fill1DHist(
3463  tmbHead->ALCTMatchTime(), "TMB_ALCTMatchTime", "TMB_ALCTMatchTime", 7, -0.5, 6.5, "TimeMonitoring");
3464 
3466  "TMB_ALCTMatchTime",
3467  "TMB_ALCTMatchTime",
3468  layer.chamberId(),
3469  7,
3470  -0.5,
3471  6.5,
3472  "TimeMonitoring");
3473 
3474  histos->fillProfile(chamberSerial(layer.chamberId()),
3475  tmbHead->ALCTMatchTime(),
3476  "prof_TMB_ALCTMatchTime",
3477  "prof_TMB_ALCTMatchTime",
3478  601,
3479  -0.5,
3480  600.5,
3481  -0.5,
3482  7.5,
3483  "TimeMonitoring");
3484  histos->fillProfile(ALCT0Key,
3485  tmbHead->ALCTMatchTime(),
3486  "prof_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3487  "prof_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3488  128,
3489  -0.5,
3490  127.5,
3491  0,
3492  7,
3493  "TimeMonitoring");
3494  histos->fillProfileByType(ALCT0Key,
3495  tmbHead->ALCTMatchTime(),
3496  "prf_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3497  "prf_TMB_ALCTMatchTime_v_ALCT0KeyWG",
3498  layer.chamberId(),
3499  128,
3500  -0.5,
3501  127.5,
3502  0,
3503  7,
3504  "TimeMonitoring");
3505 
3506  //Attempt to make a few sum plots
3507 
3508  int TMB_ALCT_rel_L1A = tmbHead->BXNCount() - (CLCTPretrigger + 2 + tmbHead->ALCTMatchTime());
3509  if (TMB_ALCT_rel_L1A > 3563)
3510  TMB_ALCT_rel_L1A = TMB_ALCT_rel_L1A - 3564;
3511  if (TMB_ALCT_rel_L1A < 0)
3512  TMB_ALCT_rel_L1A = TMB_ALCT_rel_L1A + 3564;
3513 
3514  //Plot TMB_ALCT_rel_L1A
3515  histos->fill1DHist(
3516  TMB_ALCT_rel_L1A, "h1D_TMB_ALCT_rel_L1A", "h1D_TMB_ALCT_rel_L1A", 11, 144.5, 155.5, "TimeMonitoring");
3517  histos->fill2DHist(chamberSerial(layer.chamberId()),
3518  TMB_ALCT_rel_L1A,
3519  "h2D_TMB_ALCT_rel_L1A",
3520  "h2D_TMB_ALCT_rel_L1A",
3521  601,
3522  -0.5,
3523  600.5,
3524  11,
3525  144.5,
3526  155.5,
3527  "TimeMonitoring");
3528  histos->fill2DHist(ringSerial(layer.chamberId()),
3529  TMB_ALCT_rel_L1A,
3530  "h2D_TMB_ALCT_rel_L1A_by_ring",
3531  "h2D_TMB_ALCT_rel_L1A_by_ring",
3532  19,
3533  -9.5,
3534  9.5,
3535  11,
3536  144.5,
3537  155.5,
3538  "TimeMonitoring");
3539  histos->fillProfile(chamberSerial(layer.chamberId()),
3540  TMB_ALCT_rel_L1A,
3541  "prof_TMB_ALCT_rel_L1A",
3542  "prof_TMB_ALCT_rel_L1A",
3543  601,
3544  -0.5,
3545  600.5,
3546  145,
3547  155,
3548  "TimeMonitoring");
3549  histos->fillProfile(ringSerial(layer.chamberId()),
3550  TMB_ALCT_rel_L1A,
3551  "prof_TMB_ALCT_rel_L1A_by_ring",
3552  "prof_TMB_ALCT_rel_L1A_by_ring",
3553  19,
3554  -9.5,
3555  9.5,
3556  145,
3557  155,
3558  "TimeMonitoring");
3559 
3560  histos->fill2DHist(ALCT0Key,
3561  TMB_ALCT_rel_L1A,
3562  "h2D_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3563  "h2D_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3564  128,
3565  -0.5,
3566  127.5,
3567  11,
3568  144.5,
3569  155.5,
3570  "TimeMonitoring");
3571  histos->fillProfile(ALCT0Key,
3572  TMB_ALCT_rel_L1A,
3573  "prof_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3574  "prof_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3575  128,
3576  -0.5,
3577  127.5,
3578  145,
3579  155,
3580  "TimeMonitoring");
3581  histos->fillProfileByType(ALCT0Key,
3582  TMB_ALCT_rel_L1A,
3583  "prf_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3584  "prf_TMB_ALCT_rel_L1A_v_ALCT0KeyWG",
3585  layer.chamberId(),
3586  128,
3587  -0.5,
3588  127.5,
3589  145,
3590  155,
3591  "TimeMonitoring");
3592  }
3593 
3594  } // end CSCData loop
3595  } // end ddu data loop
3596  } // end if goodEvent
3597  if (examiner != nullptr)
3598  delete examiner;
3599  } // end if non-zero fed data
3600  } // end DCC loop for NON-REFERENCE
3601 }

References CSCTMBHeader::ALCTMatchTime(), CSCTMBHeader::BXNCount(), relativeConstraints::chamber, CSCGeometry::chamber(), CSCDetId::chamberId(), RPCNoise_example::check, CSCDCCExaminer::check(), CSCDCCExaminer::crcALCT(), CSCDCCExaminer::crcCFEB(), CSCDCCExaminer::crcTMB(), dtChamberEfficiency_cfi::cscSegments, FEDRawData::data(), data, CSCDCCEventData::dduData(), CSCCrateMap::detId(), CSCDetId::endcap(), CSCDCCExaminer::errors(), FEDRawDataCollection::FEDData(), edm::EventSetup::get(), get, L1MuGMTReadoutCollection::getRecords(), combine::histos, triggerObjects_cff::id, dqmiolumiharvest::j, phase1PixelTopology::layer, LogTrace, FEDNumbering::MAXCSCFEDID, FEDNumbering::MINCSCFEDID, edm::ESHandle< T >::product(), FastTimerService_cff::range, FastTrackerRecHitMaskProducer_cfi::recHits, CSCDetId::ring(), CSCDCCExaminer::setMask(), FEDRawData::size(), jetUpdater_cfi::sort, mathSSE::sqrt(), CSCDetId::station(), GeomDet::toGlobal(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

◆ doTrigger()

bool CSCValidation::doTrigger ( edm::Handle< L1MuGMTReadoutCollection pCollection)
private

Definition at line 555 of file CSCValidation.cc.

555  {
556  std::vector<L1MuGMTReadoutRecord> L1Mrec = pCollection->getRecords();
557  std::vector<L1MuGMTReadoutRecord>::const_iterator igmtrr;
558 
559  bool csc_l1a = false;
560  bool dt_l1a = false;
561  bool rpcf_l1a = false;
562  bool rpcb_l1a = false;
563  bool beamHaloTrigger = false;
564 
565  int myBXNumber = -1000;
566 
567  for (igmtrr = L1Mrec.begin(); igmtrr != L1Mrec.end(); igmtrr++) {
568  std::vector<L1MuRegionalCand>::const_iterator iter1;
569  std::vector<L1MuRegionalCand> rmc;
570 
571  // CSC
572  int icsc = 0;
573  rmc = igmtrr->getCSCCands();
574  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
575  if (!(*iter1).empty()) {
576  icsc++;
577  int kQuality = (*iter1).quality(); // kQuality = 1 means beam halo
578  if (kQuality == 1)
579  beamHaloTrigger = true;
580  }
581  }
582  if (igmtrr->getBxInEvent() == 0 && icsc > 0)
583  csc_l1a = true;
584  if (igmtrr->getBxInEvent() == 0) {
585  myBXNumber = igmtrr->getBxNr();
586  }
587 
588  // DT
589  int idt = 0;
590  rmc = igmtrr->getDTBXCands();
591  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
592  if (!(*iter1).empty()) {
593  idt++;
594  }
595  }
596  if (igmtrr->getBxInEvent() == 0 && idt > 0)
597  dt_l1a = true;
598 
599  // RPC Barrel
600  int irpcb = 0;
601  rmc = igmtrr->getBrlRPCCands();
602  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
603  if (!(*iter1).empty()) {
604  irpcb++;
605  }
606  }
607  if (igmtrr->getBxInEvent() == 0 && irpcb > 0)
608  rpcb_l1a = true;
609 
610  // RPC Forward
611  int irpcf = 0;
612  rmc = igmtrr->getFwdRPCCands();
613  for (iter1 = rmc.begin(); iter1 != rmc.end(); iter1++) {
614  if (!(*iter1).empty()) {
615  irpcf++;
616  }
617  }
618  if (igmtrr->getBxInEvent() == 0 && irpcf > 0)
619  rpcf_l1a = true;
620  }
621 
622  // Fill some histograms with L1A info
623  if (csc_l1a)
624  histos->fill1DHist(myBXNumber, "vtBXNumber", "BX Number", 4001, -0.5, 4000.5, "Trigger");
625  if (csc_l1a)
626  histos->fill1DHist(1, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
627  if (dt_l1a)
628  histos->fill1DHist(2, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
629  if (rpcb_l1a)
630  histos->fill1DHist(3, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
631  if (rpcf_l1a)
632  histos->fill1DHist(4, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
633  if (beamHaloTrigger)
634  histos->fill1DHist(8, "vtBits", "trigger bits", 11, -0.5, 10.5, "Trigger");
635 
636  if (csc_l1a) {
637  histos->fill1DHist(1, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
638  if (dt_l1a)
639  histos->fill1DHist(2, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
640  if (rpcb_l1a)
641  histos->fill1DHist(3, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
642  if (rpcf_l1a)
643  histos->fill1DHist(4, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
644  if (dt_l1a || rpcb_l1a || rpcf_l1a)
645  histos->fill1DHist(5, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
646  if (!(dt_l1a || rpcb_l1a || rpcf_l1a))
647  histos->fill1DHist(6, "vtCSCY", "trigger bits", 11, -0.5, 10.5, "Trigger");
648  } else {
649  histos->fill1DHist(1, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
650  if (dt_l1a)
651  histos->fill1DHist(2, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
652  if (rpcb_l1a)
653  histos->fill1DHist(3, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
654  if (rpcf_l1a)
655  histos->fill1DHist(4, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
656  if (dt_l1a || rpcb_l1a || rpcf_l1a)
657  histos->fill1DHist(5, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
658  if (!(dt_l1a || rpcb_l1a || rpcf_l1a))
659  histos->fill1DHist(6, "vtCSCN", "trigger bits", 11, -0.5, 10.5, "Trigger");
660  }
661 
662  // if valid CSC L1A then return true for possible use elsewhere
663 
664  if (csc_l1a)
665  return true;
666 
667  return false;
668 }

References L1MuGMTReadoutCollection::getRecords(), and combine::histos.

◆ doWireDigis()

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

Definition at line 776 of file CSCValidation.cc.

776  {
777  int nWireGroupsTotal = 0;
778  for (CSCWireDigiCollection::DigiRangeIterator dWDiter = wires->begin(); dWDiter != wires->end(); dWDiter++) {
779  CSCDetId id = (CSCDetId)(*dWDiter).first;
780  std::vector<CSCWireDigi>::const_iterator wireIter = (*dWDiter).second.first;
781  std::vector<CSCWireDigi>::const_iterator lWire = (*dWDiter).second.second;
782  for (; wireIter != lWire; ++wireIter) {
783  int myWire = wireIter->getWireGroup();
784  int myTBin = wireIter->getTimeBin();
785  nWireGroupsTotal++;
786  histos->fill1DHistByType(myWire, "hWireWire", "Wiregroup Numbers Fired", id, 113, -0.5, 112.5, "Digis");
787  histos->fill1DHistByType(myTBin, "hWireTBin", "Wire TimeBin Fired", id, 17, -0.5, 16.5, "Digis");
789  chamberSerial(id), myTBin, "hWireTBinProfile", "Wire TimeBin Fired", 601, -0.5, 600.5, -0.5, 16.5, "Digis");
790  if (detailedAnalysis) {
792  myWire, "hWireWire", "Wiregroup Numbers Fired", id, 113, -0.5, 112.5, "WireNumberByLayer");
793  histos->fill1DHistByLayer(myTBin, "hWireTBin", "Wire TimeBin Fired", id, 17, -0.5, 16.5, "WireTimeByLayer");
794  }
795  }
796  } // end wire loop
797 
798  // this way you can zero suppress but still store info on # events with no digis
799  if (nWireGroupsTotal == 0)
800  nWireGroupsTotal = -1;
801 
802  histos->fill1DHist(nWireGroupsTotal, "hWirenGroupsTotal", "Wires Fired Per Event", 151, -0.5, 150.5, "Digis");
803 }

References dtNoiseAnalysis_cfi::detailedAnalysis, cms::cuda::for(), combine::histos, and DigiDM_cff::wires.

◆ endJob()

void CSCValidation::endJob ( void  )
overridevirtual

Reimplemented from edm::EDAnalyzer.

Definition at line 3603 of file CSCValidation.cc.

3603 { std::cout << "Events in " << nEventsAnalyzed << std::endl; }

References gather_cfg::cout.

◆ extrapolate1D()

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

Definition at line 187 of file CSCValidation.h.

187  {
188  double extrapolatedPosition = initPosition + initDirection * parameterOfTheLine;
189  return extrapolatedPosition;
190  }

◆ fillEfficiencyHistos()

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

◆ filterEvents()

bool CSCValidation::filterEvents ( edm::Handle< CSCRecHit2DCollection recHits,
edm::Handle< CSCSegmentCollection cscSegments,
edm::Handle< reco::TrackCollection saMuons 
)
private

Definition at line 337 of file CSCValidation.cc.

339  {
340  //int nGoodSAMuons = 0;
341 
342  if (recHits->size() < 4 || recHits->size() > 100)
343  return false;
344  if (cscSegments->size() < 1 || cscSegments->size() > 15)
345  return false;
346  return true;
347  //if (saMuons->size() != 1) return false;
348  /*
349  for(reco::TrackCollection::const_iterator muon = saMuons->begin(); muon != saMuons->end(); ++ muon ) {
350  double p = muon->p();
351  double reducedChisq = muon->normalizedChi2();
352 
353  GlobalPoint innerPnt(muon->innerPosition().x(),muon->innerPosition().y(),muon->innerPosition().z());
354  GlobalPoint outerPnt(muon->outerPosition().x(),muon->outerPosition().y(),muon->outerPosition().z());
355  GlobalVector innerKin(muon->innerMomentum().x(),muon->innerMomentum().y(),muon->innerMomentum().z());
356  GlobalVector outerKin(muon->outerMomentum().x(),muon->outerMomentum().y(),muon->outerMomentum().z());
357  GlobalVector deltaPnt = innerPnt - outerPnt;
358  double crudeLength = deltaPnt.mag();
359  double deltaPhi = innerPnt.phi() - outerPnt.phi();
360  double innerGlobalPolarAngle = innerKin.theta();
361  double outerGlobalPolarAngle = outerKin.theta();
362 
363  int nCSCHits = 0;
364  for (trackingRecHit_iterator hit = muon->recHitsBegin(); hit != muon->recHitsEnd(); ++hit ) {
365  if ( (*hit)->isValid() ) {
366  const DetId detId( (*hit)->geographicalId() );
367  if (detId.det() == DetId::Muon) {
368  if (detId.subdetId() == MuonSubdetId::CSC) {
369  nCSCHits++;
370  } // this is a CSC hit
371  } // this is a muon hit
372  } // hit is valid
373  } // end loop over rechits
374 
375  bool goodSAMuon = (p > pMin)
376  && ( reducedChisq < chisqMax )
377  && ( nCSCHits >= nCSCHitsMin )
378  && ( nCSCHits <= nCSCHitsMax )
379  && ( crudeLength > lengthMin )
380  && ( crudeLength < lengthMax );
381 
382 
383  goodSAMuon = goodSAMuon && ( fabs(deltaPhi) < deltaPhiMax );
384  goodSAMuon = goodSAMuon &&
385  (
386  ( ( innerGlobalPolarAngle > polarMin) && ( innerGlobalPolarAngle < polarMax) ) ||
387  ( (M_PI-innerGlobalPolarAngle > polarMin) && (M_PI-innerGlobalPolarAngle < polarMax) )
388  );
389  goodSAMuon = goodSAMuon &&
390  (
391  ( ( outerGlobalPolarAngle > polarMin) && ( outerGlobalPolarAngle < polarMax) ) ||
392  ( (M_PI-outerGlobalPolarAngle > polarMin) && (M_PI-outerGlobalPolarAngle < polarMax) )
393  );
394 
395  //goodSAMuon = goodSAMuon && (nCSCHits > nCSCHitsMin) && (nCSCHits < 13);
396  //goodSAMuon = goodSAMuon && (nCSCHits > 13) && (nCSCHits < 19);
397  //goodSAMuon = goodSAMuon && (nCSCHits > 19) && (nCSCHits < nCSCHitsMax);
398 
399 
400  if (goodSAMuon) nGoodSAMuons++;
401 
402  } // end loop over stand-alone muon collection
403 
404 
405  histos->fill1DHist(nGoodSAMuons,"hNGoodMuons", "Number of Good STA Muons per Event",11,-0.5,10.5,"STAMuons");
406 
407  if (nGoodSAMuons == 1) return true;
408  return false;
409  */
410 }

References dtChamberEfficiency_cfi::cscSegments, and FastTrackerRecHitMaskProducer_cfi::recHits.

◆ findNonAssociatedRecHits()

void CSCValidation::findNonAssociatedRecHits ( edm::ESHandle< CSCGeometry cscGeom,
edm::Handle< CSCStripDigiCollection strips 
)
private

Definition at line 2026 of file CSCValidation.cc.

2027  {
2028  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator allRHiter = AllRechits.begin(); allRHiter != AllRechits.end();
2029  ++allRHiter) {
2030  CSCDetId idRH = allRHiter->first;
2031  LocalPoint lpRH = (allRHiter->second).localPosition();
2032  float xrec = lpRH.x();
2033  float yrec = lpRH.y();
2034  float zrec = lpRH.z();
2035 
2036  bool foundmatch = false;
2037  multimap<CSCDetId, CSCRecHit2D>::iterator segRHit;
2038  segRHit = SegRechits.find(idRH);
2039  if (segRHit != SegRechits.end()) {
2040  for (; segRHit != SegRechits.upper_bound(idRH); ++segRHit) {
2041  LocalPoint lposRH = (segRHit->second).localPosition();
2042  float xpos = lposRH.x();
2043  float ypos = lposRH.y();
2044  float zpos = lposRH.z();
2045 
2046  if (xrec == xpos && yrec == ypos && zrec == zpos) {
2047  foundmatch = true;
2048  }
2049 
2050  float d = 0.;
2051  float dclose = 1000.;
2052 
2053  if (!foundmatch) {
2054  d = sqrt(pow(xrec - xpos, 2) + pow(yrec - ypos, 2) + pow(zrec - zpos, 2));
2055  if (d < dclose) {
2056  dclose = d;
2057  if (distRHmap.find((allRHiter->second)) ==
2058  distRHmap.end()) { // entry for rechit does not yet exist, create one
2059  distRHmap.insert(make_pair(allRHiter->second, dclose));
2060  } else {
2061  // we already have an entry for the detid.
2062  distRHmap.erase(allRHiter->second);
2063  distRHmap.insert(
2064  make_pair(allRHiter->second, dclose)); // fill rechits for the segment with the given detid
2065  }
2066  }
2067  }
2068  }
2069  }
2070  if (!foundmatch) {
2071  NonAssociatedRechits.insert(std::pair<CSCDetId, CSCRecHit2D>(idRH, allRHiter->second));
2072  }
2073  }
2074 
2075  for (std::map<CSCRecHit2D, float, ltrh>::iterator iter = distRHmap.begin(); iter != distRHmap.end(); ++iter) {
2076  histos->fill1DHist(iter->second,
2077  "hdistRH",
2078  "Distance of Non Associated RecHit from closest Segment RecHit",
2079  500,
2080  0.,
2081  100.,
2082  "NonAssociatedRechits");
2083  }
2084 
2085  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator iter = NonAssociatedRechits.begin();
2086  iter != NonAssociatedRechits.end();
2087  ++iter) {
2088  CSCDetId idrec = iter->first;
2089  int kEndcap = idrec.endcap();
2090  int cEndcap = idrec.endcap();
2091  if (kEndcap == 2)
2092  cEndcap = -1;
2093  int kRing = idrec.ring();
2094  int kStation = idrec.station();
2095  int kChamber = idrec.chamber();
2096  int kLayer = idrec.layer();
2097 
2098  // Store rechit as a Local Point:
2099  LocalPoint rhitlocal = (iter->second).localPosition();
2100  float xreco = rhitlocal.x();
2101  float yreco = rhitlocal.y();
2102 
2103  // Find the strip containing this hit
2104  int centerid = (iter->second).nStrips() / 2;
2105  int centerStrip = (iter->second).channels(centerid);
2106 
2107  // Find the charge associated with this hit
2108  float rHSumQ = 0;
2109  float sumsides = 0.;
2110  int adcsize = (iter->second).nStrips() * (iter->second).nTimeBins();
2111  for (unsigned int i = 0; i < (iter->second).nStrips(); i++) {
2112  for (unsigned int j = 0; j < (iter->second).nTimeBins() - 1; j++) {
2113  rHSumQ += (iter->second).adcs(i, j);
2114  if (i != 1)
2115  sumsides += (iter->second).adcs(i, j);
2116  }
2117  }
2118 
2119  float rHratioQ = sumsides / rHSumQ;
2120  if (adcsize != 12)
2121  rHratioQ = -99;
2122 
2123  // Get the signal timing of this hit
2124  float rHtime = (iter->second).tpeak() / 50;
2125 
2126  // Get the width of this hit
2127  int rHwidth = getWidth(*strips, idrec, centerStrip);
2128 
2129  // Get pointer to the layer:
2130  const CSCLayer* csclayer = cscGeom->layer(idrec);
2131 
2132  // Transform hit position from local chamber geometry to global CMS geom
2133  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
2134  float grecx = rhitglobal.x();
2135  float grecy = rhitglobal.y();
2136 
2137  // Simple occupancy variables
2138  int kCodeBroad = cEndcap * (4 * (kStation - 1) + kRing);
2139  int kCodeNarrow = cEndcap * (100 * (kRing - 1) + kChamber);
2140 
2141  //Fill the non-associated rechits parameters in histogram
2142  histos->fill1DHist(
2143  kCodeBroad, "hNARHCodeBroad", "broad scope code for recHits", 33, -16.5, 16.5, "NonAssociatedRechits");
2144  if (kStation == 1)
2145  histos->fill1DHist(kCodeNarrow,
2146  "hNARHCodeNarrow1",
2147  "narrow scope recHit code station 1",
2148  801,
2149  -400.5,
2150  400.5,
2151  "NonAssociatedRechits");
2152  if (kStation == 2)
2153  histos->fill1DHist(kCodeNarrow,
2154  "hNARHCodeNarrow2",
2155  "narrow scope recHit code station 2",
2156  801,
2157  -400.5,
2158  400.5,
2159  "NonAssociatedRechits");
2160  if (kStation == 3)
2161  histos->fill1DHist(kCodeNarrow,
2162  "hNARHCodeNarrow3",
2163  "narrow scope recHit code station 3",
2164  801,
2165  -400.5,
2166  400.5,
2167  "NonAssociatedRechits");
2168  if (kStation == 4)
2169  histos->fill1DHist(kCodeNarrow,
2170  "hNARHCodeNarrow4",
2171  "narrow scope recHit code station 4",
2172  801,
2173  -400.5,
2174  400.5,
2175  "NonAssociatedRechits");
2176  histos->fill1DHistByType(kLayer, "hNARHLayer", "RecHits per Layer", idrec, 8, -0.5, 7.5, "NonAssociatedRechits");
2177  histos->fill1DHistByType(xreco, "hNARHX", "Local X of recHit", idrec, 160, -80., 80., "NonAssociatedRechits");
2178  histos->fill1DHistByType(yreco, "hNARHY", "Local Y of recHit", idrec, 60, -180., 180., "NonAssociatedRechits");
2179  if (kStation == 1 && (kRing == 1 || kRing == 4))
2181  rHSumQ, "hNARHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 4000, "NonAssociatedRechits");
2182  else
2184  rHSumQ, "hNARHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 2000, "NonAssociatedRechits");
2186  rHratioQ, "hNARHRatioQ", "Ratio (Ql+Qr)/Qt)", idrec, 120, -0.1, 1.1, "NonAssociatedRechits");
2187  histos->fill1DHistByType(rHtime, "hNARHTiming", "recHit Timing", idrec, 200, -10, 10, "NonAssociatedRechits");
2188  histos->fill2DHistByStation(grecx,
2189  grecy,
2190  "hNARHGlobal",
2191  "recHit Global Position",
2192  idrec,
2193  400,
2194  -800.,
2195  800.,
2196  400,
2197  -800.,
2198  800.,
2199  "NonAssociatedRechits");
2201  rHwidth, "hNARHwidth", "width for Non associated recHit", idrec, 21, -0.5, 20.5, "NonAssociatedRechits");
2202  }
2203 
2204  for (std::multimap<CSCDetId, CSCRecHit2D>::iterator iter = SegRechits.begin(); iter != SegRechits.end(); ++iter) {
2205  CSCDetId idrec = iter->first;
2206  int kEndcap = idrec.endcap();
2207  int cEndcap = idrec.endcap();
2208  if (kEndcap == 2)
2209  cEndcap = -1;
2210  int kRing = idrec.ring();
2211  int kStation = idrec.station();
2212  int kChamber = idrec.chamber();
2213  int kLayer = idrec.layer();
2214 
2215  // Store rechit as a Local Point:
2216  LocalPoint rhitlocal = (iter->second).localPosition();
2217  float xreco = rhitlocal.x();
2218  float yreco = rhitlocal.y();
2219 
2220  // Find the strip containing this hit
2221  int centerid = (iter->second).nStrips() / 2;
2222  int centerStrip = (iter->second).channels(centerid);
2223 
2224  // Find the charge associated with this hit
2225 
2226  float rHSumQ = 0;
2227  float sumsides = 0.;
2228  int adcsize = (iter->second).nStrips() * (iter->second).nTimeBins();
2229  for (unsigned int i = 0; i < (iter->second).nStrips(); i++) {
2230  for (unsigned int j = 0; j < (iter->second).nTimeBins() - 1; j++) {
2231  rHSumQ += (iter->second).adcs(i, j);
2232  if (i != 1)
2233  sumsides += (iter->second).adcs(i, j);
2234  }
2235  }
2236 
2237  float rHratioQ = sumsides / rHSumQ;
2238  if (adcsize != 12)
2239  rHratioQ = -99;
2240 
2241  // Get the signal timing of this hit
2242  float rHtime = (iter->second).tpeak() / 50;
2243 
2244  // Get the width of this hit
2245  int rHwidth = getWidth(*strips, idrec, centerStrip);
2246 
2247  // Get pointer to the layer:
2248  const CSCLayer* csclayer = cscGeom->layer(idrec);
2249 
2250  // Transform hit position from local chamber geometry to global CMS geom
2251  GlobalPoint rhitglobal = csclayer->toGlobal(rhitlocal);
2252  float grecx = rhitglobal.x();
2253  float grecy = rhitglobal.y();
2254 
2255  // Simple occupancy variables
2256  int kCodeBroad = cEndcap * (4 * (kStation - 1) + kRing);
2257  int kCodeNarrow = cEndcap * (100 * (kRing - 1) + kChamber);
2258 
2259  //Fill the non-associated rechits global position in histogram
2260  histos->fill1DHist(
2261  kCodeBroad, "hSegRHCodeBroad", "broad scope code for recHits", 33, -16.5, 16.5, "AssociatedRechits");
2262  if (kStation == 1)
2263  histos->fill1DHist(kCodeNarrow,
2264  "hSegRHCodeNarrow1",
2265  "narrow scope recHit code station 1",
2266  801,
2267  -400.5,
2268  400.5,
2269  "AssociatedRechits");
2270  if (kStation == 2)
2271  histos->fill1DHist(kCodeNarrow,
2272  "hSegRHCodeNarrow2",
2273  "narrow scope recHit code station 2",
2274  801,
2275  -400.5,
2276  400.5,
2277  "AssociatedRechits");
2278  if (kStation == 3)
2279  histos->fill1DHist(kCodeNarrow,
2280  "hSegRHCodeNarrow3",
2281  "narrow scope recHit code station 3",
2282  801,
2283  -400.5,
2284  400.5,
2285  "AssociatedRechits");
2286  if (kStation == 4)
2287  histos->fill1DHist(kCodeNarrow,
2288  "hSegRHCodeNarrow4",
2289  "narrow scope recHit code station 4",
2290  801,
2291  -400.5,
2292  400.5,
2293  "AssociatedRechits");
2294  histos->fill1DHistByType(kLayer, "hSegRHLayer", "RecHits per Layer", idrec, 8, -0.5, 7.5, "AssociatedRechits");
2295  histos->fill1DHistByType(xreco, "hSegRHX", "Local X of recHit", idrec, 160, -80., 80., "AssociatedRechits");
2296  histos->fill1DHistByType(yreco, "hSegRHY", "Local Y of recHit", idrec, 60, -180., 180., "AssociatedRechits");
2297  if (kStation == 1 && (kRing == 1 || kRing == 4))
2298  histos->fill1DHistByType(rHSumQ, "hSegRHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 4000, "AssociatedRechits");
2299  else
2300  histos->fill1DHistByType(rHSumQ, "hSegRHSumQ", "Sum 3x3 recHit Charge", idrec, 250, 0, 2000, "AssociatedRechits");
2301  histos->fill1DHistByType(rHratioQ, "hSegRHRatioQ", "Ratio (Ql+Qr)/Qt)", idrec, 120, -0.1, 1.1, "AssociatedRechits");
2302  histos->fill1DHistByType(rHtime, "hSegRHTiming", "recHit Timing", idrec, 200, -10, 10, "AssociatedRechits");
2303  histos->fill2DHistByStation(grecx,
2304  grecy,
2305  "hSegRHGlobal",
2306  "recHit Global Position",
2307  idrec,
2308  400,
2309  -800.,
2310  800.,
2311  400,
2312  -800.,
2313  800.,
2314  "AssociatedRechits");
2316  rHwidth, "hSegRHwidth", "width for Non associated recHit", idrec, 21, -0.5, 20.5, "AssociatedRechits");
2317  }
2318 
2319  distRHmap.clear();
2320  AllRechits.clear();
2321  SegRechits.clear();
2322  NonAssociatedRechits.clear();
2323 }

References CSCDetId::chamber(), ewkTauDQM_cfi::channels, ztail::d, CSCDetId::endcap(), combine::histos, mps_fire::i, dqmiolumiharvest::j, kLayer(), CSCDetId::layer(), CSCGeometry::layer(), me0TriggerPseudoDigis_cff::nStrips, dtSegmentTask_hlt_cfi::nTimeBins, funct::pow(), CSCDetId::ring(), mathSSE::sqrt(), CSCDetId::station(), DigiDM_cff::strips, GeomDet::toGlobal(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

◆ fitX()

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

Definition at line 1422 of file CSCValidation.cc.

1422  {
1423  float S = 0;
1424  float Sx = 0;
1425  float Sy = 0;
1426  float Sxx = 0;
1427  float Sxy = 0;
1428  float sigma2 = 0;
1429 
1430  for (int i = 1; i < 7; i++) {
1431  if (i != 3) {
1432  sigma2 = errors(i, 1) * errors(i, 1);
1433  S = S + (1 / sigma2);
1434  Sy = Sy + (points(i, 1) / sigma2);
1435  Sx = Sx + ((i) / sigma2);
1436  Sxx = Sxx + (i * i) / sigma2;
1437  Sxy = Sxy + (((i)*points(i, 1)) / sigma2);
1438  }
1439  }
1440 
1441  float delta = S * Sxx - Sx * Sx;
1442  float intercept = (Sxx * Sy - Sx * Sxy) / delta;
1443  float slope = (S * Sxy - Sx * Sy) / delta;
1444 
1445  //float chi = 0;
1446  //float chi2 = 0;
1447 
1448  // calculate chi2 (not currently used)
1449  //for (int i=1;i<7;i++){
1450  // chi = (points(i,1) - intercept - slope*i)/(errors(i,1));
1451  // chi2 = chi2 + chi*chi;
1452  //}
1453 
1454  return (intercept + slope * 3);
1455 }

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

◆ getEfficiency()

void CSCValidation::getEfficiency ( float  bin,
float  Norm,
std::vector< float > &  eff 
)
private

Definition at line 1764 of file CSCValidation.cc.

1764  {
1765  //---- Efficiency with binomial error
1766  float Efficiency = 0.;
1767  float EffError = 0.;
1768  if (fabs(Norm) > 0.000000001) {
1769  Efficiency = bin / Norm;
1770  if (bin < Norm) {
1771  EffError = sqrt((1. - Efficiency) * Efficiency / Norm);
1772  }
1773  }
1774  eff[0] = Efficiency;
1775  eff[1] = EffError;
1776 }

References newFWLiteAna::bin, PixelTestBeamValidation_cfi::Efficiency, and mathSSE::sqrt().

◆ getSignal()

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

Definition at line 1902 of file CSCValidation.cc.

1902  {
1903  float SigADC[5];
1904  float TotalADC = 0;
1905  SigADC[0] = 0;
1906  SigADC[1] = 0;
1907  SigADC[2] = 0;
1908  SigADC[3] = 0;
1909  SigADC[4] = 0;
1910 
1911  // Loop over strip digis
1913 
1914  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
1915  CSCDetId id = (CSCDetId)(*sIt).first;
1916  if (id == idCS) {
1917  // First, find the Signal-Pedestal for center strip
1918  std::vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
1919  std::vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
1920  for (; digiItr != last; ++digiItr) {
1921  int thisStrip = digiItr->getStrip();
1922  if (thisStrip == (centerStrip)) {
1923  std::vector<int> myADCVals = digiItr->getADCCounts();
1924  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1925  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1926  SigADC[0] = thisSignal - 6 * thisPedestal;
1927  }
1928  // Now,find the Signal-Pedestal for neighbouring 4 strips
1929  if (thisStrip == (centerStrip + 1)) {
1930  std::vector<int> myADCVals = digiItr->getADCCounts();
1931  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1932  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1933  SigADC[1] = thisSignal - 6 * thisPedestal;
1934  }
1935  if (thisStrip == (centerStrip + 2)) {
1936  std::vector<int> myADCVals = digiItr->getADCCounts();
1937  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1938  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1939  SigADC[2] = thisSignal - 6 * thisPedestal;
1940  }
1941  if (thisStrip == (centerStrip - 1)) {
1942  std::vector<int> myADCVals = digiItr->getADCCounts();
1943  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1944  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1945  SigADC[3] = thisSignal - 6 * thisPedestal;
1946  }
1947  if (thisStrip == (centerStrip - 2)) {
1948  std::vector<int> myADCVals = digiItr->getADCCounts();
1949  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
1950  float thisSignal = (myADCVals[2] + myADCVals[3] + myADCVals[4] + myADCVals[5] + myADCVals[6] + myADCVals[7]);
1951  SigADC[4] = thisSignal - 6 * thisPedestal;
1952  }
1953  }
1954  TotalADC = 0.2 * (SigADC[0] + SigADC[1] + SigADC[2] + SigADC[3] + SigADC[4]);
1955  }
1956  }
1957  return TotalADC;
1958 }

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

◆ getthisSignal()

float CSCValidation::getthisSignal ( const CSCStripDigiCollection stripdigis,
CSCDetId  idRH,
int  centerStrip 
)
private

Definition at line 2325 of file CSCValidation.cc.

2325  {
2326  // Loop over strip digis responsible for this recHit
2328  float thisADC = 0.;
2329  //bool foundRHid = false;
2330  // std::cout<<"iD S/R/C/L = "<<idRH<<" "<<idRH.station()<<"/"<<idRH.ring()<<"/"<<idRH.chamber()<<"/"<<idRH.layer()<<std::endl;
2331  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
2332  CSCDetId id = (CSCDetId)(*sIt).first;
2333  //std::cout<<"STRIPS: id S/R/C/L = "<<id<<" "<<id.station()<<"/"<<id.ring()<<"/"<<id.chamber()<<"/"<<id.layer()<<std::endl;
2334  if (id == idRH) {
2335  //foundRHid = true;
2336  vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
2337  vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
2338  //if(digiItr == last ) {std::cout << " Attention1 :: Size of digi collection is zero " << std::endl;}
2339  int St = idRH.station();
2340  int Rg = idRH.ring();
2341  if (St == 1 && Rg == 4) {
2342  while (centerStrip > 16)
2343  centerStrip -= 16;
2344  }
2345  for (; digiItr != last; ++digiItr) {
2346  int thisStrip = digiItr->getStrip();
2347  //std::cout<<" thisStrip = "<<thisStrip<<" centerStrip = "<<centerStrip<<std::endl;
2348  std::vector<int> myADCVals = digiItr->getADCCounts();
2349  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2350  float Signal = (float)myADCVals[3];
2351  if (thisStrip == (centerStrip)) {
2352  thisADC = Signal - thisPedestal;
2353  //if(thisADC >= 0. && thisADC <2.) {std::cout << " Attention2 :: The Signal is equal to the pedestal " << std::endl;
2354  //}
2355  //if(thisADC < 0.) {std::cout << " Attention3 :: The Signal is less than the pedestal " << std::endl;
2356  //}
2357  }
2358  if (thisStrip == (centerStrip + 1)) {
2359  std::vector<int> myADCVals = digiItr->getADCCounts();
2360  }
2361  if (thisStrip == (centerStrip - 1)) {
2362  std::vector<int> myADCVals = digiItr->getADCCounts();
2363  }
2364  }
2365  }
2366  }
2367  //if(!foundRHid){std::cout << " Attention4 :: Did not find a matching RH id in the Strip Digi collection " << std::endl;}
2368  return thisADC;
2369 }

References dqmMemoryStats::float, if(), dqmdumpme::last, ExhumeParameters_cfi::Rg, CSCDetId::ring(), and CSCDetId::station().

◆ getWidth()

int CSCValidation::getWidth ( const CSCStripDigiCollection stripdigis,
CSCDetId  idRH,
int  centerStrip 
)
private

Definition at line 2377 of file CSCValidation.cc.

2377  {
2378  int width = 1;
2379  int widthpos = 0;
2380  int widthneg = 0;
2381 
2382  // Loop over strip digis responsible for this recHit and sum charge
2384 
2385  for (sIt = stripdigis.begin(); sIt != stripdigis.end(); sIt++) {
2386  CSCDetId id = (CSCDetId)(*sIt).first;
2387  if (id == idRH) {
2388  std::vector<CSCStripDigi>::const_iterator digiItr = (*sIt).second.first;
2389  std::vector<CSCStripDigi>::const_iterator first = (*sIt).second.first;
2390  std::vector<CSCStripDigi>::const_iterator last = (*sIt).second.second;
2391  std::vector<CSCStripDigi>::const_iterator it = (*sIt).second.first;
2392  std::vector<CSCStripDigi>::const_iterator itr = (*sIt).second.first;
2393  //std::cout << " IDRH " << id <<std::endl;
2394  int St = idRH.station();
2395  int Rg = idRH.ring();
2396  if (St == 1 && Rg == 4) {
2397  while (centerStrip > 16)
2398  centerStrip -= 16;
2399  }
2400  for (; digiItr != last; ++digiItr) {
2401  int thisStrip = digiItr->getStrip();
2402  if (thisStrip == (centerStrip)) {
2403  it = digiItr;
2404  for (; it != last; ++it) {
2405  int strip = it->getStrip();
2406  std::vector<int> myADCVals = it->getADCCounts();
2407  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2408  if (((float)myADCVals[3] - thisPedestal) < 6 || widthpos == 10 || it == last) {
2409  break;
2410  }
2411  if (strip != centerStrip) {
2412  widthpos += 1;
2413  }
2414  }
2415  itr = digiItr;
2416  for (; itr != first; --itr) {
2417  int strip = itr->getStrip();
2418  std::vector<int> myADCVals = itr->getADCCounts();
2419  float thisPedestal = 0.5 * (float)(myADCVals[0] + myADCVals[1]);
2420  if (((float)myADCVals[3] - thisPedestal) < 6 || widthneg == 10 || itr == first) {
2421  break;
2422  }
2423  if (strip != centerStrip) {
2424  widthneg += 1;
2425  }
2426  }
2427  }
2428  }
2429  }
2430  }
2431  //std::cout << "Widthneg - " << widthneg << "Widthpos + " << widthpos << std::endl;
2432  width = width + widthneg + widthpos;
2433  //std::cout << "Width " << width << std::endl;
2434  return width;
2435 }

References first, dqmMemoryStats::float, if(), dqmdumpme::last, ExhumeParameters_cfi::Rg, CSCDetId::ring(), CSCDetId::station(), digitizers_cfi::strip, and ApeEstimator_cff::width.

◆ histoEfficiency()

void CSCValidation::histoEfficiency ( TH1F *  readHisto,
TH1F *  writeHisto 
)
private

Definition at line 1778 of file CSCValidation.cc.

1778  {
1779  std::vector<float> eff(2);
1780  int Nbins = readHisto->GetSize() - 2; //without underflows and overflows
1781  std::vector<float> bins(Nbins);
1782  std::vector<float> Efficiency(Nbins);
1783  std::vector<float> EffError(Nbins);
1784  float Num = 1;
1785  float Den = 1;
1786  for (int i = 0; i < 20; i++) {
1787  Num = readHisto->GetBinContent(i + 1);
1788  Den = readHisto->GetBinContent(i + 21);
1789  getEfficiency(Num, Den, eff);
1790  Efficiency[i] = eff[0];
1791  EffError[i] = eff[1];
1792  writeHisto->SetBinContent(i + 1, Efficiency[i]);
1793  writeHisto->SetBinError(i + 1, EffError[i]);
1794  }
1795 }

References trigObjTnPSource_cfi::bins, PixelTestBeamValidation_cfi::Efficiency, mps_fire::i, and SiStripMonitorCluster_cfi::Nbins.

◆ lineParametrization()

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

Definition at line 183 of file CSCValidation.h.

183  {
184  double parameterLine = (z2Position - z1Position) / z1Direction;
185  return parameterLine;
186  }

◆ ringSerial()

int CSCValidation::ringSerial ( CSCDetId  id)
private

Definition at line 1393 of file CSCValidation.cc.

1393  {
1394  int st = id.station();
1395  int ri = id.ring();
1396  int ec = id.endcap();
1397  int kSerial = 0;
1398  if (st == 1 && ri == 1)
1399  kSerial = ri;
1400  if (st == 1 && ri == 2)
1401  kSerial = ri;
1402  if (st == 1 && ri == 3)
1403  kSerial = ri;
1404  if (st == 1 && ri == 4)
1405  kSerial = 1;
1406  if (st == 2)
1407  kSerial = ri + 3;
1408  if (st == 3)
1409  kSerial = ri + 5;
1410  if (st == 4)
1411  kSerial = ri + 7;
1412  if (ec == 2)
1413  kSerial = kSerial * (-1);
1414  return kSerial;
1415 }

◆ typeIndex()

int CSCValidation::typeIndex ( CSCDetId  id)
inlineprivate

Definition at line 306 of file CSCValidation.h.

306  {
307  // linearlized index bases on endcap, station, and ring
308  int index = 0;
309  if (id.station() == 1) {
310  index = id.ring() + 1;
311  if (id.ring() == 4)
312  index = 1;
313  } else
314  index = id.station() * 2 + id.ring();
315  if (id.endcap() == 1)
316  index = index + 10;
317  if (id.endcap() == 2)
318  index = 11 - index;
319  return index;
320  }

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

◆ withinSensitiveRegion()

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

Definition at line 1797 of file CSCValidation.cc.

1802  {
1803  //---- check if it is in a good local region (sensitive area - geometrical and HV boundaries excluded)
1804  bool pass = false;
1805 
1806  float y_center = 0.;
1807  double yUp = layerBounds[3] + y_center;
1808  double yDown = -layerBounds[3] + y_center;
1809  double xBound1Shifted = layerBounds[0] - shiftFromEdge; //
1810  double xBound2Shifted = layerBounds[1] - shiftFromEdge; //
1811  double lineSlope = (yUp - yDown) / (xBound2Shifted - xBound1Shifted);
1812  double lineConst = yUp - lineSlope * xBound2Shifted;
1813  double yBorder = lineSlope * abs(localPos.x()) + lineConst;
1814 
1815  //bool withinChamberOnly = false;// false = "good region"; true - boundaries only
1816  std::vector<float> deadZoneCenter(6);
1817  float cutZone = shiftFromDeadZone; //cm
1818  //---- hardcoded... not good
1819  if (station > 1 && station < 5) {
1820  if (2 == ring) {
1821  deadZoneCenter[0] = -162.48;
1822  deadZoneCenter[1] = -81.8744;
1823  deadZoneCenter[2] = -21.18165;
1824  deadZoneCenter[3] = 39.51105;
1825  deadZoneCenter[4] = 100.2939;
1826  deadZoneCenter[5] = 160.58;
1827 
1828  if (localPos.y() > yBorder &&
1829  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1830  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1831  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone) ||
1832  (localPos.y() > deadZoneCenter[3] + cutZone && localPos.y() < deadZoneCenter[4] - cutZone) ||
1833  (localPos.y() > deadZoneCenter[4] + cutZone && localPos.y() < deadZoneCenter[5] - cutZone))) {
1834  pass = true;
1835  }
1836  } else if (1 == ring) {
1837  if (2 == station) {
1838  deadZoneCenter[0] = -95.80;
1839  deadZoneCenter[1] = -27.47;
1840  deadZoneCenter[2] = 33.67;
1841  deadZoneCenter[3] = 90.85;
1842  } else if (3 == station) {
1843  deadZoneCenter[0] = -89.305;
1844  deadZoneCenter[1] = -39.705;
1845  deadZoneCenter[2] = 20.195;
1846  deadZoneCenter[3] = 77.395;
1847  } else if (4 == station) {
1848  deadZoneCenter[0] = -75.645;
1849  deadZoneCenter[1] = -26.055;
1850  deadZoneCenter[2] = 23.855;
1851  deadZoneCenter[3] = 70.575;
1852  }
1853  if (localPos.y() > yBorder &&
1854  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1855  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1856  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1857  pass = true;
1858  }
1859  }
1860  } else if (1 == station) {
1861  if (3 == ring) {
1862  deadZoneCenter[0] = -83.155;
1863  deadZoneCenter[1] = -22.7401;
1864  deadZoneCenter[2] = 27.86665;
1865  deadZoneCenter[3] = 81.005;
1866  if (localPos.y() > yBorder &&
1867  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1868  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1869  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1870  pass = true;
1871  }
1872  } else if (2 == ring) {
1873  deadZoneCenter[0] = -86.285;
1874  deadZoneCenter[1] = -32.88305;
1875  deadZoneCenter[2] = 32.867423;
1876  deadZoneCenter[3] = 88.205;
1877  if (localPos.y() > (yBorder) &&
1878  ((localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone) ||
1879  (localPos.y() > deadZoneCenter[1] + cutZone && localPos.y() < deadZoneCenter[2] - cutZone) ||
1880  (localPos.y() > deadZoneCenter[2] + cutZone && localPos.y() < deadZoneCenter[3] - cutZone))) {
1881  pass = true;
1882  }
1883  } else {
1884  deadZoneCenter[0] = -81.0;
1885  deadZoneCenter[1] = 81.0;
1886  if (localPos.y() > (yBorder) &&
1887  (localPos.y() > deadZoneCenter[0] + cutZone && localPos.y() < deadZoneCenter[1] - cutZone)) {
1888  pass = true;
1889  }
1890  }
1891  }
1892  return pass;
1893 }

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

Member Data Documentation

◆ al_token

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

Definition at line 239 of file CSCValidation.h.

◆ AllRechits

std::multimap<CSCDetId, CSCRecHit2D> CSCValidation::AllRechits
private

Definition at line 301 of file CSCValidation.h.

◆ cd_token

edm::EDGetTokenT<CSCComparatorDigiCollection> CSCValidation::cd_token
private

Definition at line 238 of file CSCValidation.h.

◆ chisqMax

double CSCValidation::chisqMax
private

Definition at line 229 of file CSCValidation.h.

◆ cl_token

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

Definition at line 240 of file CSCValidation.h.

◆ cleanEvent

bool CSCValidation::cleanEvent
private

Definition at line 203 of file CSCValidation.h.

◆ co_token

edm::EDGetTokenT<CSCCorrelatedLCTDigiCollection> CSCValidation::co_token
private

Definition at line 241 of file CSCValidation.h.

◆ deltaPhiMax

double CSCValidation::deltaPhiMax
private

Definition at line 232 of file CSCValidation.h.

◆ detailedAnalysis

bool CSCValidation::detailedAnalysis
private

Definition at line 219 of file CSCValidation.h.

◆ distRHmap

std::map<CSCRecHit2D, float, ltrh> CSCValidation::distRHmap
private

Definition at line 304 of file CSCValidation.h.

◆ firstEvent

bool CSCValidation::firstEvent
private

Definition at line 202 of file CSCValidation.h.

◆ geomToken_

edm::ESGetToken<CSCGeometry, MuonGeometryRecord> CSCValidation::geomToken_
private

Definition at line 248 of file CSCValidation.h.

◆ hEffDenominator

TH2F* CSCValidation::hEffDenominator
private

Definition at line 286 of file CSCValidation.h.

◆ histos

CSCValHists* CSCValidation::histos
private

Definition at line 271 of file CSCValidation.h.

Referenced by DisplayManager.DisplayManager::Draw().

◆ hORecHits

TH2I* CSCValidation::hORecHits
private

Definition at line 292 of file CSCValidation.h.

◆ hOSegments

TH2I* CSCValidation::hOSegments
private

Definition at line 293 of file CSCValidation.h.

◆ hOStrips

TH2I* CSCValidation::hOStrips
private

Definition at line 291 of file CSCValidation.h.

◆ hOWires

TH2I* CSCValidation::hOWires
private

Definition at line 290 of file CSCValidation.h.

◆ hRHEff

TH1F* CSCValidation::hRHEff
private

Definition at line 277 of file CSCValidation.h.

◆ hRHEff2

TH2F* CSCValidation::hRHEff2
private

Definition at line 283 of file CSCValidation.h.

◆ hRHSTE

TH1F* CSCValidation::hRHSTE
private

Definition at line 275 of file CSCValidation.h.

◆ hRHSTE2

TH2F* CSCValidation::hRHSTE2
private

Definition at line 279 of file CSCValidation.h.

◆ hSEff

TH1F* CSCValidation::hSEff
private

Definition at line 276 of file CSCValidation.h.

◆ hSEff2

TH2F* CSCValidation::hSEff2
private

Definition at line 282 of file CSCValidation.h.

◆ hSensitiveAreaEvt

TH2F* CSCValidation::hSensitiveAreaEvt
private

Definition at line 287 of file CSCValidation.h.

◆ hSSTE

TH1F* CSCValidation::hSSTE
private

Definition at line 274 of file CSCValidation.h.

◆ hSSTE2

TH2F* CSCValidation::hSSTE2
private

Definition at line 278 of file CSCValidation.h.

◆ hStripEff2

TH2F* CSCValidation::hStripEff2
private

Definition at line 284 of file CSCValidation.h.

◆ hStripSTE2

TH2F* CSCValidation::hStripSTE2
private

Definition at line 280 of file CSCValidation.h.

◆ hWireEff2

TH2F* CSCValidation::hWireEff2
private

Definition at line 285 of file CSCValidation.h.

◆ hWireSTE2

TH2F* CSCValidation::hWireSTE2
private

Definition at line 281 of file CSCValidation.h.

◆ isSimulation

bool CSCValidation::isSimulation
private

Definition at line 217 of file CSCValidation.h.

◆ l1_token

edm::EDGetTokenT<L1MuGMTReadoutCollection> CSCValidation::l1_token
private

Definition at line 244 of file CSCValidation.h.

◆ lengthMax

double CSCValidation::lengthMax
private

Definition at line 231 of file CSCValidation.h.

◆ lengthMin

double CSCValidation::lengthMin
private

Definition at line 231 of file CSCValidation.h.

◆ m_single_wire_layer

std::map<int, int> CSCValidation::m_single_wire_layer
private

Definition at line 298 of file CSCValidation.h.

◆ m_wire_hvsegm

std::map<int, std::vector<int> > CSCValidation::m_wire_hvsegm
private

Definition at line 297 of file CSCValidation.h.

◆ makeADCTimingPlots

bool CSCValidation::makeADCTimingPlots
private

Definition at line 264 of file CSCValidation.h.

◆ makeAFEBTimingPlots

bool CSCValidation::makeAFEBTimingPlots
private

Definition at line 262 of file CSCValidation.h.

◆ makeCalibPlots

bool CSCValidation::makeCalibPlots
private

Definition at line 266 of file CSCValidation.h.

◆ makeComparisonPlots

bool CSCValidation::makeComparisonPlots
private

Definition at line 214 of file CSCValidation.h.

◆ makeCompTimingPlots

bool CSCValidation::makeCompTimingPlots
private

Definition at line 263 of file CSCValidation.h.

◆ makeEfficiencyPlots

bool CSCValidation::makeEfficiencyPlots
private

Definition at line 260 of file CSCValidation.h.

◆ makeGasGainPlots

bool CSCValidation::makeGasGainPlots
private

Definition at line 261 of file CSCValidation.h.

◆ makeHLTPlots

bool CSCValidation::makeHLTPlots
private

Definition at line 221 of file CSCValidation.h.

◆ makeOccupancyPlots

bool CSCValidation::makeOccupancyPlots
private

Definition at line 251 of file CSCValidation.h.

◆ makePedNoisePlots

bool CSCValidation::makePedNoisePlots
private

Definition at line 259 of file CSCValidation.h.

◆ makePlots

bool CSCValidation::makePlots
private

Definition at line 213 of file CSCValidation.h.

◆ makeRecHitPlots

bool CSCValidation::makeRecHitPlots
private

Definition at line 255 of file CSCValidation.h.

◆ makeResolutionPlots

bool CSCValidation::makeResolutionPlots
private

Definition at line 258 of file CSCValidation.h.

◆ makeRHNoisePlots

bool CSCValidation::makeRHNoisePlots
private

Definition at line 265 of file CSCValidation.h.

◆ makeSegmentPlots

bool CSCValidation::makeSegmentPlots
private

Definition at line 257 of file CSCValidation.h.

◆ makeSimHitPlots

bool CSCValidation::makeSimHitPlots
private

Definition at line 256 of file CSCValidation.h.

◆ makeStandalonePlots

bool CSCValidation::makeStandalonePlots
private

Definition at line 267 of file CSCValidation.h.

◆ makeStripPlots

bool CSCValidation::makeStripPlots
private

Definition at line 253 of file CSCValidation.h.

◆ makeTimeMonitorPlots

bool CSCValidation::makeTimeMonitorPlots
private

Definition at line 268 of file CSCValidation.h.

◆ makeTriggerPlots

bool CSCValidation::makeTriggerPlots
private

Definition at line 252 of file CSCValidation.h.

◆ makeWirePlots

bool CSCValidation::makeWirePlots
private

Definition at line 254 of file CSCValidation.h.

◆ nCSCHitsMax

int CSCValidation::nCSCHitsMax
private

Definition at line 230 of file CSCValidation.h.

◆ nCSCHitsMin

int CSCValidation::nCSCHitsMin
private

Definition at line 230 of file CSCValidation.h.

◆ nEventsAnalyzed

int CSCValidation::nEventsAnalyzed
private

Definition at line 199 of file CSCValidation.h.

◆ nmbhvsegm

std::vector<int> CSCValidation::nmbhvsegm
private

Maps and vectors for module doGasGain()

Definition at line 296 of file CSCValidation.h.

◆ NonAssociatedRechits

std::multimap<CSCDetId, CSCRecHit2D> CSCValidation::NonAssociatedRechits
private

Definition at line 303 of file CSCValidation.h.

◆ pMin

double CSCValidation::pMin
private

Definition at line 228 of file CSCValidation.h.

◆ polarMax

double CSCValidation::polarMax
private

Definition at line 233 of file CSCValidation.h.

◆ polarMin

double CSCValidation::polarMin
private

Definition at line 233 of file CSCValidation.h.

◆ rd_token

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

Definition at line 235 of file CSCValidation.h.

◆ refRootFile

std::string CSCValidation::refRootFile
private

Definition at line 215 of file CSCValidation.h.

◆ rh_token

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

Definition at line 242 of file CSCValidation.h.

◆ rhTreeCount

int CSCValidation::rhTreeCount
private

Definition at line 200 of file CSCValidation.h.

◆ rootFileName

std::string CSCValidation::rootFileName
private

Definition at line 218 of file CSCValidation.h.

◆ sa_token

edm::EDGetTokenT<reco::TrackCollection> CSCValidation::sa_token
private

Definition at line 246 of file CSCValidation.h.

◆ sd_token

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

Definition at line 237 of file CSCValidation.h.

◆ se_token

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

Definition at line 243 of file CSCValidation.h.

◆ SegRechits

std::multimap<CSCDetId, CSCRecHit2D> CSCValidation::SegRechits
private

Definition at line 302 of file CSCValidation.h.

◆ segTreeCount

int CSCValidation::segTreeCount
private

Definition at line 201 of file CSCValidation.h.

◆ sh_token

edm::EDGetTokenT<edm::PSimHitContainer> CSCValidation::sh_token
private

Definition at line 247 of file CSCValidation.h.

◆ theFile

TFile* CSCValidation::theFile
private

Definition at line 208 of file CSCValidation.h.

◆ tr_token

edm::EDGetTokenT<edm::TriggerResults> CSCValidation::tr_token
private

Definition at line 245 of file CSCValidation.h.

◆ useDigis

bool CSCValidation::useDigis
private

Definition at line 220 of file CSCValidation.h.

◆ useQualityFilter

bool CSCValidation::useQualityFilter
private

Definition at line 224 of file CSCValidation.h.

◆ useTriggerFilter

bool CSCValidation::useTriggerFilter
private

Definition at line 225 of file CSCValidation.h.

◆ wd_token

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

Definition at line 236 of file CSCValidation.h.

◆ writeTreeToFile

bool CSCValidation::writeTreeToFile
private

Definition at line 216 of file CSCValidation.h.

Vector3DBase
Definition: Vector3DBase.h:8
CSCValidation::al_token
edm::EDGetTokenT< CSCALCTDigiCollection > al_token
Definition: CSCValidation.h:239
edm::ESHandle::product
T const * product() const
Definition: ESHandle.h:86
change_name.diff
diff
Definition: change_name.py:13
CSCValidation::makeCalibPlots
bool makeCalibPlots
Definition: CSCValidation.h:266
FastTimerService_cff.range
range
Definition: FastTimerService_cff.py:34
DDAxes::y
ApeEstimator_cff.width
width
Definition: ApeEstimator_cff.py:24
CSCValidation::fitX
float fitX(const CLHEP::HepMatrix &sp, const CLHEP::HepMatrix &ep)
Definition: CSCValidation.cc:1422
CSCValHists::fillCalibHist
void fillCalibHist(float x, std::string name, std::string title, int bins, float xmin, float xmax, int bin, std::string folder)
Definition: CSCValHists.cc:82
CSCValidation::segTreeCount
int segTreeCount
Definition: CSCValidation.h:201
MuonSubdetId::CSC
static constexpr int CSC
Definition: MuonSubdetId.h:12
CSCDBPedestalsRcd
Definition: CSCDBPedestalsRcd.h:5
CSCValHists::fillProfileByType
void fillProfileByType(float x, float y, std::string name, std::string title, CSCDetId id, int binsx, float xmin, float xmax, float ymin, float ymax, std::string folder)
Definition: CSCValHists.cc:481
CSCValidation::doTrigger
bool doTrigger(edm::Handle< L1MuGMTReadoutCollection > pCollection)
Definition: CSCValidation.cc:555
runGCPTkAlMap.title
string title
Definition: runGCPTkAlMap.py:94
ExhumeParameters_cfi.Rg
Rg
Definition: ExhumeParameters_cfi.py:6
CSCDBPedestals::pedestals
PedestalContainer pedestals
Definition: CSCDBPedestals.h:26
mps_fire.i
i
Definition: mps_fire.py:428
CSCValidation::lengthMax
double lengthMax
Definition: CSCValidation.h:231
CSCValidation::doRecHits
void doRecHits(edm::Handle< CSCRecHit2DCollection > recHits, edm::ESHandle< CSCGeometry > cscGeom)
Definition: CSCValidation.cc:896
CSCValidation::doEfficiencies
void doEfficiencies(edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
Definition: CSCValidation.cc:1462
CSCValidation::co_token
edm::EDGetTokenT< CSCCorrelatedLCTDigiCollection > co_token
Definition: CSCValidation.h:241
CSCValidation::doOccupancies
void doOccupancies(edm::Handle< CSCStripDigiCollection > strips, edm::Handle< CSCWireDigiCollection > wires, edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments)
Definition: CSCValidation.cc:418
dqmMemoryStats.float
float
Definition: dqmMemoryStats.py:127
CSCValidation::makeTriggerPlots
bool makeTriggerPlots
Definition: CSCValidation.h:252
CSCChamber::layer
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to the given id.
Definition: CSCChamber.cc:30
dqmiodumpmetadata.n
n
Definition: dqmiodumpmetadata.py:28
CSCValidation::rh_token
edm::EDGetTokenT< CSCRecHit2DCollection > rh_token
Definition: CSCValidation.h:242
CSCValHists::setupTrees
void setupTrees()
Definition: CSCValHists.cc:39
CSCDCCEventData::dduData
const std::vector< CSCDDUEventData > & dduData() const
accessor to dduData
Definition: CSCDCCEventData.h:25
CSCDCCExaminer::errors
ExaminerStatusType errors(void) const
Definition: CSCDCCExaminer.h:169
CSCValidation::rd_token
edm::EDGetTokenT< FEDRawDataCollection > rd_token
Definition: CSCValidation.h:235
HLT_FULL_cff.points
points
Definition: HLT_FULL_cff.py:21453
LocalError::xy
float xy() const
Definition: LocalError.h:23
muon
Definition: MuonCocktails.h:17
PV3DBase::x
T x() const
Definition: PV3DBase.h:59
CSCValidation::hOStrips
TH2I * hOStrips
Definition: CSCValidation.h:291
ChiSquaredProbability
float ChiSquaredProbability(double chiSquared, double nrDOF)
Definition: ChiSquaredProbability.cc:13
relativeConstraints.station
station
Definition: relativeConstraints.py:67
CSCDetId::ring
int ring() const
Definition: CSCDetId.h:68
DigiDM_cff.wires
wires
Definition: DigiDM_cff.py:33
digitizers_cfi.strip
strip
Definition: digitizers_cfi.py:19
mps_merge.weight
weight
Definition: mps_merge.py:88
CSCValidation::nmbhvsegm
std::vector< int > nmbhvsegm
Maps and vectors for module doGasGain()
Definition: CSCValidation.h:296
PV3DBase::theta
Geom::Theta< T > theta() const
Definition: PV3DBase.h:72
CSCValidation::detailedAnalysis
bool detailedAnalysis
Definition: CSCValidation.h:219
CSCDCCEventData
01/20/05 A.Tumanov
Definition: CSCDCCEventData.h:13
RPCDetId
Definition: RPCDetId.h:16
gather_cfg.cout
cout
Definition: gather_cfg.py:144
np
int np
Definition: AMPTWrapper.h:43
CSCValidation::ringSerial
int ringSerial(CSCDetId id)
Definition: CSCValidation.cc:1393
CSCValidation::rootFileName
std::string rootFileName
Definition: CSCValidation.h:218
CSCValidation::m_single_wire_layer
std::map< int, int > m_single_wire_layer
Definition: CSCValidation.h:298
CSCValidation::doResolution
void doResolution(edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom)
Definition: CSCValidation.cc:1175
CSCValidation::histos
CSCValHists * histos
Definition: CSCValidation.h:271
CSCValidation::NonAssociatedRechits
std::multimap< CSCDetId, CSCRecHit2D > NonAssociatedRechits
Definition: CSCValidation.h:303
if
if(0==first)
Definition: CAHitNtupletGeneratorKernelsImpl.h:48
FEDNumbering::MAXCSCFEDID
Definition: FEDNumbering.h:52
FastTrackerRecHitCombiner_cfi.simHits
simHits
Definition: FastTrackerRecHitCombiner_cfi.py:5
CSCValidation::makeTimeMonitorPlots
bool makeTimeMonitorPlots
Definition: CSCValidation.h:268
CSCValidation::hSSTE
TH1F * hSSTE
Definition: CSCValidation.h:274
CSCLayer
Definition: CSCLayer.h:24
dtChamberEfficiency_cfi.cscSegments
cscSegments
Definition: dtChamberEfficiency_cfi.py:15
DDAxes::x
CSCDBNoiseMatrix::matrix
NoiseMatrixContainer matrix
Definition: CSCDBNoiseMatrix.h:24
CSCValHists::fill1DHist
void fill1DHist(float x, std::string name, std::string title, int bins, float xmin, float xmax, std::string folder)
Definition: CSCValHists.cc:93
Signal
hltPixelTracks_cff.chi2
chi2
Definition: hltPixelTracks_cff.py:25
makeMuonMisalignmentScenario.endcap
endcap
Definition: makeMuonMisalignmentScenario.py:320
CSCValidation::doTimeMonitoring
void doTimeMonitoring(edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::Handle< CSCALCTDigiCollection > alcts, edm::Handle< CSCCLCTDigiCollection > clcts, edm::Handle< CSCCorrelatedLCTDigiCollection > correlatedlcts, edm::Handle< L1MuGMTReadoutCollection > pCollection, edm::ESHandle< CSCGeometry > cscGeom, const edm::EventSetup &eventSetup, const edm::Event &event)
Definition: CSCValidation.cc:2933
edm::Handle< CSCWireDigiCollection >
CSCValidation::polarMax
double polarMax
Definition: CSCValidation.h:233
CSCValidation::isSimulation
bool isSimulation
Definition: CSCValidation.h:217
CSCDBCrosstalkRcd
Definition: CSCDBCrosstalkRcd.h:5
CSCValHists::fill1DHistByLayer
void fill1DHistByLayer(float x, std::string name, std::string title, CSCDetId id, int bins, float xmin, float xmax, std::string folder)
Definition: CSCValHists.cc:401
CSCValidation::doNoiseHits
void doNoiseHits(edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< CSCSegmentCollection > cscSegments, edm::ESHandle< CSCGeometry > cscGeom, edm::Handle< CSCStripDigiCollection > strips)
Definition: CSCValidation.cc:1965
CSCValidation::cleanEvent
bool cleanEvent
Definition: CSCValidation.h:203
FEDRawData::data
const unsigned char * data() const
Return a const pointer to the beginning of the data buffer.
Definition: FEDRawData.cc:24
CSCValidation::lengthMin
double lengthMin
Definition: CSCValidation.h:231
MuonDigiCollection::const_iterator
std::vector< DigiType >::const_iterator const_iterator
Definition: MuonDigiCollection.h:94
CSCValidation::hStripSTE2
TH2F * hStripSTE2
Definition: CSCValidation.h:280
FEDRawData
Definition: FEDRawData.h:19
CSCValidation::hSSTE2
TH2F * hSSTE2
Definition: CSCValidation.h:278
CSCDBGains
Definition: CSCDBGains.h:9
CSCValidation::hSEff
TH1F * hSEff
Definition: CSCValidation.h:276
CSCValidation::tr_token
edm::EDGetTokenT< edm::TriggerResults > tr_token
Definition: CSCValidation.h:245
PixelTestBeamValidation_cfi.Efficiency
Efficiency
Definition: PixelTestBeamValidation_cfi.py:79
CSCValidation::chamberSerial
int chamberSerial(CSCDetId id)
Definition: CSCValidation.cc:1358
PV3DBase::z
T z() const
Definition: PV3DBase.h:61
CSCValidation::hSensitiveAreaEvt
TH2F * hSensitiveAreaEvt
Definition: CSCValidation.h:287
CSCValidation::doCalibrations
void doCalibrations(const edm::EventSetup &eventSetup)
Definition: CSCValidation.cc:693
CSCValHists::writeTrees
void writeTrees(TFile *theFile)
Definition: CSCValHists.cc:29
CSCDBCrosstalk
Definition: CSCDBCrosstalk.h:9
contentValuesCheck.ss
ss
Definition: contentValuesCheck.py:33
CSCValidation::getthisSignal
float getthisSignal(const CSCStripDigiCollection &stripdigis, CSCDetId idRH, int centerStrip)
Definition: CSCValidation.cc:2325
DetId
Definition: DetId.h:17
CSCValidation::doWireDigis
void doWireDigis(edm::Handle< CSCWireDigiCollection > wires)
Definition: CSCValidation.cc:776
CSCValidation::doSimHits
void doSimHits(edm::Handle< CSCRecHit2DCollection > recHits, edm::Handle< edm::PSimHitContainer > simHits)
Definition: CSCValidation.cc:1029
CSCValidation::nCSCHitsMax
int nCSCHitsMax
Definition: CSCValidation.h:230
alignCSCRings.s
s
Definition: alignCSCRings.py:92
RPCNoise_example.check
check
Definition: RPCNoise_example.py:71
dqmdumpme.last
last
Definition: dqmdumpme.py:56
CSCValHists::fillProfile
void fillProfile(float x, float y, std::string name, std::string title, int binsx, float xmin, float xmax, float ymin, float ymax, std::string folder)
Definition: CSCValHists.cc:461
CSCValHists::writeHists
void writeHists(TFile *theFile)
Definition: CSCValHists.cc:10
edm::EventSetup::get
T get() const
Definition: EventSetup.h:87
CSCDBPedestals
Definition: CSCDBPedestals.h:9
SiPixelRawToDigiRegional_cfi.deltaPhi
deltaPhi
Definition: SiPixelRawToDigiRegional_cfi.py:9
CSCValidation::makeWirePlots
bool makeWirePlots
Definition: CSCValidation.h:254
CSCValidation::lineParametrization
double lineParametrization(double z1Position, double z2Position, double z1Direction)
Definition: CSCValidation.h:183
LocalError::xx
float xx() const
Definition: LocalError.h:22
CSCValidation::hWireEff2
TH2F * hWireEff2
Definition: CSCValidation.h:285
HLT_FULL_cff.muon
muon
Definition: HLT_FULL_cff.py:11710
CSCValHists::insertPlot
void insertPlot(TH1 *thePlot, std::string name, std::string folder)
Definition: CSCValHists.cc:78
TrapezoidalPlaneBounds::parameters
virtual const std::array< const float, 4 > parameters() const
Definition: TrapezoidalPlaneBounds.cc:49
CSCLayerGeometry
Definition: CSCLayerGeometry.h:25
mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:19
CSCIndexer
Definition: CSCIndexer.h:44
CSCDetId::layer
int layer() const
Definition: CSCDetId.h:56
edm::ESHandle< CSCGeometry >
ADC
Definition: ZdcTBAnalysis.h:46
CSCValidation::doAFEBTiming
void doAFEBTiming(const CSCWireDigiCollection &)
Definition: CSCValidation.cc:2715
CSCChamber
Definition: CSCChamber.h:22
CSCValidation::getEfficiency
void getEfficiency(float bin, float Norm, std::vector< float > &eff)
Definition: CSCValidation.cc:1764
CSCValHists
Definition: CSCValHists.h:32
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Definition: CSCValidation.cc:1902
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Definition: CSCLayer.h:44
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Definition: MuonSubdetId.h:11
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Definition: CSCValidation.h:202
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Definition: GlobalPoint.h:10
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Definition: CSCValidation.h:243
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Definition: CSCValidation.cc:2026
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Definition: HIMultiTrackSelector.h:42
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Definition: CSCValidation.h:233
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Definition: CSCSegment.h:21
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Definition: CSCDBGains.h:24
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Definition: CSCValHists.cc:425
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Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
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Definition: MessageLogger.h:233
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Definition: CSCValidation.cc:2377
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Definition: CSCDetId.h:26
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Definition: CSCChamberSpecs.cc:156
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Definition: CSCValidation.h:261
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Definition: CSCValidation.h:255
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Definition: CSCValidation.h:265
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Definition: PV3DBase.h:60
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Definition: createfilelist.py:10
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Definition: CSCGeometry.h:30
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Definition: CSCValidation.h:230
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Definition: CSCValidation.h:253
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Definition: CSCDetId.h:47
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Definition: CSCDetId.h:62
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Definition: CSCValidation.h:277
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Definition: CSCValidation.h:221
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Definition: CSCValidation.h:248
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Definition: CSCChamber.h:39
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Definition: CSCValidation.h:228
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Definition: CSCValidation.h:251
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Definition: CSCValidation.h:260
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Definition: HistoContainer.h:27
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Lenght of the data buffer in bytes.
Definition: FEDRawData.h:45
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Definition: CSCValidation.cc:2442
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Definition: CSCValidation.h:229
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1.2 is to make the matching window safely the two nearest strips 0.35 is the size of an ME0 chamber i...
Definition: me0TriggerPseudoDigis_cff.py:26
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Definition: alignCSCRings.py:93
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Definition: newFWLiteAna.py:161
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Definition: CSCTMBHeader.h:26
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Definition: PV3DBase.h:64
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Definition: CSCValHists.cc:50
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Definition: CSCValidation.h:279
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Definition: CSCValidation.h:236
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Definition: CSCValidation.cc:2843
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Definition: CSCValidation.h:259
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Definition: CSCValidation.cc:337
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Return the layer corresponding to given DetId.
Definition: CSCGeometry.cc:105
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Definition: CSCDBCrosstalk.h:28
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Definition: CSCValidation.h:256
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Definition: CSCDCCExaminer.cc:37
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Definition: CSCIndexer.cc:231
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Definition: triggerObjects_cff.py:29
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Definition: CSCDetId.h:85
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Definition: CSCValidation.h:302
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Definition: CSCValHists.cc:231
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Definition: CSCValidation.h:237
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Definition: ewkTauDQM_cfi.py:14
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Definition: CSCDCCExaminer.cc:29
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Definition: CSCValidation.h:290
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Definition: CSCValHists.cc:288
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Definition: relativeConstraints.py:68
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Definition: CSCValidation.h:267
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Definition: CSCCrateMap.cc:9
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Definition: CSCValidation.cc:1797
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Definition: CSCValidation.h:216
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Definition: relativeConstraints.py:53
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Definition: CSCValidation.h:238
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Definition: CSCCrateMapRcd.h:5
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Definition: Skims_PA_cff.py:17
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Definition: CSCDBGainsRcd.h:5
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Definition: CSCValidation.cc:1081
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Definition: CSCTMBHeader.h:38
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Return a vector of all chambers.
Definition: CSCGeometry.cc:96
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Definition: VarParsing.py:659
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Definition: CSCValidation.h:264
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Definition: EPOS_Wrapper.h:79
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Definition: CSCDBL1TPParametersExtended.h:16
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Definition: AlignmentPayloadInspectorHelper.h:46
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Definition: CSCCrateMap.h:11
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Definition: CSCValidation.h:304
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Definition: CSCValidation.h:306
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Definition: EcalCondDBWriter_cfi.py:63
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Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29
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Definition: ztail.py:151
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Definition: CSCDCCExaminer.cc:45
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Definition: CSCValidation.h:224
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Definition: DetId.h:26
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Definition: CSCTMBHeader.h:39
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Definition: Abs.h:22
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Definition: MessageLogger.h:234
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Definition: trigObjTnPSource_cfi.py:20
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Definition: CSCValidation.h:258
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Definition: CSCValidation.h:187
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Definition: CSCDetId.h:79
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Definition: CSCValHists.cc:64
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Definition: CAHitNtupletGeneratorKernelsImpl.h:46
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Definition: dqmiolumiharvest.py:66
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Definition: CSCValidation.h:275
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Definition: CastorTimeSlew.cc:6
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Get the (concrete) DetId.
Definition: CSCChamber.h:34
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Definition: event.py:1
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Definition: remoteMonitoring_LED_IterMethod_cfg.py:430
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Definition: MuonDigiCollection.h:30
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Definition: CSCValidation.h:232
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Definition: CSCValidation.h:247
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Definition: CSCDBNoiseMatrixRcd.h:5
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Definition: CSCValidation.h:282
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Definition: CSCSegment.h:39
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Definition: CSCValidation.h:199
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Definition: CSCValidation.cc:811
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Definition: CSCValidation.h:220
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Definition: LocalError.h:24
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Definition: InputTag.h:15
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#turn off noise in all subdetectors simHcalUnsuppressedDigis.doNoise = False mix.digitizers....
Definition: DigiDM_cff.py:32
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Definition: CSCValidation.h:262
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Definition: CSCValidation.cc:1778
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Definition: PV3DBase.h:66
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Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:100
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Definition: weight.py:1
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Definition: CSCValidation.cc:2782
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Definition: SiStripHitEffFromCalibTree.cc:88
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Definition: muonDTDigis_cfi.py:27
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Definition: CSCValidation.h:293
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Definition: ValidationMatrix.py:459
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Definition: MillePedeFileConverter_cfg.py:37
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Definition: CSCValidation.h:283
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void fill2DHistByStation(float x, float y, std::string name, std::string title, CSCDetId id, int binsx, float xmin, float xmax, int binsy, float ymin, float ymax, std::string folder)
Definition: CSCValHists.cc:254
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Definition: debug_messages_cfi.py:54