ECAL TB 2006 calibration with matrix inversion technique. More...
#include <EcalEleCalibLooper.h>
Public Member Functions | |
void | beginOfJob () |
BeginOfJob. | |
Status | duringLoop (const edm::Event &, const edm::EventSetup &) |
EcalEleCalibLooper (const edm::ParameterSet &) | |
ctor | |
void | endOfJob () |
Status | endOfLoop (const edm::EventSetup &, unsigned int iCounter) |
void | startingNewLoop (unsigned int) |
~EcalEleCalibLooper () | |
dtor | |
Private Member Functions | |
int | EBregionCheck (const int eta, const int phi) const |
Tells if you are in the region to be calibrated. | |
void | EBRegionDefinition () |
DS EB Region Definition. | |
int | EBRegionId (const int, const int) const |
Reg Id generator EB ----- for the barrel. | |
int | EBregionsNum () const |
DS number of regions in EB. | |
int | EEregionCheck (const int, const int) const |
returns zero if the coordinates are in the right place. | |
void | EERegionDefinition () |
int | EERegionId (const int, const int) const |
Gives the id of the region. | |
int | EEregionsNum () const |
DS Number of regions in EE. | |
int | etaShifter (const int) const |
LP Change the coordinate system. | |
double | giveLimit (int) |
copes with the infinitives of the tangent | |
Private Attributes | |
bool | isfirstcall_ |
edm::InputTag | m_barrelAlCa |
EcalBarrel Input Collection name. | |
std::vector< DetId > | m_barrelCells |
EcalIntercalibConstantMap | m_barrelMap |
the maps of recalib coeffs | |
std::vector< VEcalCalibBlock * > | m_EcalCalibBlocks |
single blocks calibrators | |
edm::InputTag | m_ElectronLabel |
To take the electrons. | |
edm::InputTag | m_endcapAlCa |
EcalEndcap Input Collection name. | |
std::vector< DetId > | m_endcapCells |
EcalIntercalibConstantMap | m_endcapMap |
int | m_etaEnd |
eta end of the region of interest | |
int | m_etaStart |
phi size of the additive border to the sub-matrix | |
int | m_etaWidth |
eta size of the sub-matrix | |
unsigned int | m_loops |
DS sets the number of loops to do. | |
VFillMap * | m_MapFiller |
double | m_maxCoeff |
maximum coefficient accepted (RAW) | |
double | m_maxEnergyPerCrystal |
maximum energy per crystal cut | |
int | m_maxSelectedNumPerXtal |
maximum number of events per crystal | |
double | m_minCoeff |
minimum coefficient accepted (RAW) | |
double | m_minEnergyPerCrystal |
minimum energy per crystal cut | |
int | m_phiEndEB |
phi end of the region of interest | |
int | m_phiEndEE |
int | m_phiStartEB |
phi start of the region of interest | |
int | m_phiStartEE |
int | m_phiWidthEB |
eta size of the additive border to the sub-matrix | |
int | m_phiWidthEE |
int | m_radEnd |
int | m_radStart |
DS For the EE. | |
int | m_radWidth |
int | m_recoWindowSidex |
reconstruction window size | |
int | m_recoWindowSidey |
std::vector< int > | m_regions |
int | m_usingBlockSolver |
to exclude the blocksolver | |
std::map< int, int > | m_xtalNumOfHits |
std::map< int, int > | m_xtalPositionInRegion |
std::map< int, int > | m_xtalRegionId |
ECAL TB 2006 calibration with matrix inversion technique.
Definition at line 34 of file EcalEleCalibLooper.h.
EcalEleCalibLooper::EcalEleCalibLooper | ( | const edm::ParameterSet & | iConfig | ) | [explicit] |
ctor
LP ctor.
Graphs to ckeck the region definition
End of Graphs
Definition at line 36 of file EcalEleCalibLooper.cc.
References algorithm(), EBRegionDefinition(), EBregionsNum(), EERegionDefinition(), EEregionsNum(), eta(), cmsRelvalreport::exit, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), m_barrelMap, m_EcalCalibBlocks, m_endcapMap, m_etaEnd, m_etaStart, m_etaWidth, m_MapFiller, m_maxEnergyPerCrystal, m_minEnergyPerCrystal, m_radEnd, m_radStart, m_radWidth, m_recoWindowSidex, m_recoWindowSidey, m_regions, m_xtalPositionInRegion, m_xtalRegionId, dbtoconf::out, phi, AlCaHLTBitMon_QueryRunRegistry::string, EBDetId::unhashIndex(), EEDetId::validDetId(), x, and detailsBasic3DVector::y.
: m_barrelAlCa (iConfig.getParameter<edm::InputTag> ("alcaBarrelHitCollection")) , m_endcapAlCa (iConfig.getParameter<edm::InputTag> ("alcaEndcapHitCollection")) , m_recoWindowSidex (iConfig.getParameter<int> ("recoWindowSidex")) , m_recoWindowSidey (iConfig.getParameter<int> ("recoWindowSidey")) , m_etaWidth (iConfig.getParameter<int> ("etaWidth")) , m_phiWidthEB (iConfig.getParameter<int> ("phiWidthEB")) , m_etaStart (etaShifter (iConfig.getParameter<int> ("etaStart"))) , m_etaEnd (etaShifter (iConfig.getParameter<int> ("etaEnd"))) , m_phiStartEB (iConfig.getParameter<int> ("phiStartEB")) , m_phiEndEB (iConfig.getParameter<int> ("phiEndEB")), m_radStart (iConfig.getParameter<int> ("radStart")) , m_radEnd (iConfig.getParameter<int> ("radEnd")) , m_radWidth (iConfig.getParameter<int> ("radWidth")) , m_phiStartEE (iConfig.getParameter<int> ("phiStartEE")) , m_phiEndEE (iConfig.getParameter<int> ("phiEndEE")) , m_phiWidthEE (iConfig.getParameter<int> ("phiWidthEE")) , m_maxSelectedNumPerXtal (iConfig.getParameter<int> ("maxSelectedNumPerCrystal")) , m_minEnergyPerCrystal (iConfig.getParameter<double> ("minEnergyPerCrystal")), m_maxEnergyPerCrystal (iConfig.getParameter<double> ("maxEnergyPerCrystal")) , m_minCoeff (iConfig.getParameter<double> ("minCoeff")) , m_maxCoeff (iConfig.getParameter<double> ("maxCoeff")) , m_usingBlockSolver (iConfig.getParameter<int> ("usingBlockSolver")) , m_loops (iConfig.getParameter<int> ("loops")), m_ElectronLabel (iConfig.getParameter<edm::InputTag> ("electronLabel")) { edm::LogInfo ("IML") << "[EcalEleCalibLooper][ctor] asserts" ; assert (!((m_etaEnd - m_etaStart )%m_etaWidth)); assert (m_etaStart >=0 && m_etaStart <= 171); assert (m_etaEnd >= m_etaStart && m_etaEnd <= 171); assert ( (m_radEnd - m_radStart)%m_radWidth == 0) ; assert (m_radStart >=0 && m_radStart <= 50); assert (m_radEnd >= m_radStart && m_radEnd <= 50); edm::LogInfo ("IML") << "[EcalEleCalibLooper][ctor] entering " ; edm::LogInfo ("IML") << "[EcalEleCalibLooper][ctor] region definition" ; EBRegionDefinition () ; EERegionDefinition () ; TH2F * EBRegion = new TH2F ("EBRegion","EBRegion",170,0,170,360,0,360) ; for (int eta = 0; eta<170; ++eta) for (int phi = 0; phi <360; ++phi){ EBRegion->Fill (eta, phi,m_xtalRegionId[EBDetId::unhashIndex(eta*360+phi).rawId()] ); } TH2F * EERegion = new TH2F ("EERegion", "EERegion",100,0,100,100,0,100); for (int x = 0; x<100; ++x) for (int y = 0; y<100;++y){ if(EEDetId::validDetId(x+1,y+1,1)) EERegion->Fill(x,y,m_xtalRegionId[EEDetId(x+1,y+1,-1).rawId()]); } TFile out ("EBZone.root", "recreate"); EBRegion->Write (); EERegion->Write (); out.Close (); delete EERegion; delete EBRegion; //PG build the calibration algorithms for the regions //PG ------------------------------------------------ edm::LogInfo ("IML") << "[EcalEleCalibLooper][ctor] Calib Block" ; std::string algorithm = iConfig.getParameter<std::string> ("algorithm") ; int eventWeight = iConfig.getUntrackedParameter<int> ("L3EventWeight",1) ; //PG loop over the regions set for (int region = 0 ; region < EBregionsNum () + 2 * EEregionsNum () ; ++region) { if (algorithm == "IMA") m_EcalCalibBlocks.push_back ( new IMACalibBlock (m_regions.at (region)) ) ; else if (algorithm == "L3") m_EcalCalibBlocks.push_back ( new L3CalibBlock (m_regions.at (region), eventWeight) ) ; else { edm::LogError ("building") << algorithm << " is not a valid calibration algorithm" ; exit (1) ; } } //PG loop over the regions set std::string mapFiller = iConfig.getParameter<std::string> ("FillType"); if (mapFiller == "Cluster") m_MapFiller= new ClusterFillMap ( m_recoWindowSidex ,m_recoWindowSidey , m_xtalRegionId ,m_minEnergyPerCrystal , m_maxEnergyPerCrystal , m_xtalPositionInRegion , & m_barrelMap , & m_endcapMap ); if (mapFiller == "Matrix") m_MapFiller = new MatrixFillMap ( m_recoWindowSidex ,m_recoWindowSidey , m_xtalRegionId , m_minEnergyPerCrystal , m_maxEnergyPerCrystal , m_xtalPositionInRegion , & m_barrelMap , & m_endcapMap); } //end ctor
EcalEleCalibLooper::~EcalEleCalibLooper | ( | ) |
dtor
LP destructor.
Definition at line 142 of file EcalEleCalibLooper.cc.
References m_EcalCalibBlocks.
{ edm::LogInfo ("IML") << "[EcalEleCalibLooper][dtor]" ; for (std::vector<VEcalCalibBlock *>::iterator calibBlock = m_EcalCalibBlocks.begin () ; calibBlock != m_EcalCalibBlocks.end () ; ++calibBlock) delete (*calibBlock) ; }
void EcalEleCalibLooper::beginOfJob | ( | ) | [virtual] |
Reimplemented from edm::EDLooperBase.
Definition at line 158 of file EcalEleCalibLooper.cc.
References isfirstcall_.
{ isfirstcall_=true; }
edm::EDLooper::Status EcalEleCalibLooper::duringLoop | ( | const edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [virtual] |
duringLoop return the status Kcontinue, fills the calibBlock with the recHits
Implements edm::EDLooper.
Definition at line 194 of file EcalEleCalibLooper.cc.
References DetId::det(), DetId::Ecal, EcalBarrel, EcalEndcap, HcalObjRepresent::Fill(), VFillMap::fillMap(), first, geometry, edm::EventSetup::get(), edm::Event::getByLabel(), EcalClusterTools::getMaximum(), CaloGeometry::getValidDetIds(), isfirstcall_, edm::HandleBase::isValid(), edm::EDLooperBase::kContinue, m_barrelAlCa, m_barrelCells, m_barrelMap, m_EcalCalibBlocks, m_ElectronLabel, m_endcapAlCa, m_endcapCells, m_endcapMap, m_MapFiller, m_maxSelectedNumPerXtal, m_xtalNumOfHits, m_xtalRegionId, siStripFEDMonitor_P5_cff::Max, edm::Handle< T >::product(), and DetId::rawId().
{ // this chunk used to belong to beginJob(isetup). Moved here // with the beginJob without arguments migration if (isfirstcall_){ edm::ESHandle<CaloGeometry> geoHandle; iSetup.get<CaloGeometryRecord> ().get (geoHandle); const CaloGeometry& geometry = *geoHandle; m_barrelCells = geometry.getValidDetIds (DetId::Ecal, EcalBarrel); m_endcapCells = geometry.getValidDetIds (DetId::Ecal, EcalEndcap); for (std::vector<DetId>::const_iterator barrelIt=m_barrelCells.begin(); barrelIt!=m_barrelCells.end();++barrelIt){ m_barrelMap[*barrelIt]=1; m_xtalNumOfHits[barrelIt->rawId()]=0; } for (std::vector<DetId>::const_iterator endcapIt=m_endcapCells.begin(); endcapIt!=m_endcapCells.end();++endcapIt){ m_endcapMap[*endcapIt]=1; m_xtalNumOfHits[endcapIt->rawId()]=0; } isfirstcall_=false; } //take the collection of recHits in the barrel const EBRecHitCollection* barrelHitsCollection = 0; edm::Handle<EBRecHitCollection> barrelRecHitsHandle ; iEvent.getByLabel (m_barrelAlCa, barrelRecHitsHandle) ; barrelHitsCollection = barrelRecHitsHandle.product () ; if (!barrelRecHitsHandle.isValid ()) { edm::LogError ("reading") << "[EcalEleCalibLooper] barrel rec hits not found" ; return kContinue ; } //take the collection of rechis in the endcap const EERecHitCollection * endcapHitsCollection = 0 ; edm::Handle<EERecHitCollection> endcapRecHitsHandle ; iEvent.getByLabel (m_endcapAlCa, endcapRecHitsHandle) ; endcapHitsCollection = endcapRecHitsHandle.product () ; if (!endcapRecHitsHandle.isValid ()) { edm::LogError ("reading") << "[EcalEleCalibLooper] endcap rec hits not found" ; return kContinue; } //Takes the electron collection of the pixel detector edm::Handle<reco::GsfElectronCollection> pElectrons; iEvent.getByLabel (m_ElectronLabel,pElectrons); if (!pElectrons.isValid ()) { edm::LogError ("reading")<< "[EcalEleCalibLooper] electrons not found" ; return kContinue; } //Start the loop over the electrons for (reco::GsfElectronCollection::const_iterator eleIt = pElectrons->begin (); eleIt != pElectrons->end (); ++eleIt ) { double pSubtract = 0 ; double pTk = 0 ; std::map<int , double> xtlMap; DetId Max =0; if (fabs(eleIt->eta()<1.49)) Max = EcalClusterTools::getMaximum(eleIt->superCluster()->hitsAndFractions(),barrelHitsCollection).first; else Max = EcalClusterTools::getMaximum(eleIt->superCluster()->hitsAndFractions(),endcapHitsCollection).first; if (Max.det()==0) continue; m_MapFiller->fillMap(eleIt->superCluster ()->hitsAndFractions (),Max, barrelHitsCollection,endcapHitsCollection, xtlMap,pSubtract); if (m_maxSelectedNumPerXtal > 0 && m_xtalNumOfHits[Max.rawId ()] > m_maxSelectedNumPerXtal ) continue; ++m_xtalNumOfHits[Max.rawId()]; if (m_xtalRegionId[Max.rawId()]==-1) continue; pTk = eleIt->trackMomentumAtVtx ().R (); m_EcalCalibBlocks.at (m_xtalRegionId[Max.rawId()])->Fill (xtlMap.begin (), xtlMap.end (),pTk,pSubtract) ; } //End of the loop over the electron collection return kContinue; } //end of duringLoop
int EcalEleCalibLooper::EBregionCheck | ( | const int | eta, |
const int | phi | ||
) | const [private] |
Tells if you are in the region to be calibrated.
Definition at line 397 of file EcalEleCalibLooper.cc.
References m_etaEnd, m_etaStart, m_phiEndEB, and m_phiStartEB.
Referenced by EBRegionId().
{ if (eta < m_etaStart) return 1 ; if (eta >= m_etaEnd) return 2 ; if (phi < m_phiStartEB) return 3 ; if (phi >= m_phiEndEB) return 4 ; return 0 ; }
void EcalEleCalibLooper::EBRegionDefinition | ( | ) | [private] |
DS EB Region Definition.
Definition at line 519 of file EcalEleCalibLooper.cc.
References EBRegionId(), EBregionsNum(), eta(), m_regions, m_xtalPositionInRegion, m_xtalRegionId, phi, DetId::rawId(), and EBDetId::unhashIndex().
Referenced by EcalEleCalibLooper().
{ int reg=-1; for (int it = 0 ; it < EBregionsNum () ; ++it) m_regions.push_back (0) ; for (int eta = 0 ; eta < 170 ; ++eta) for (int phi = 0 ; phi < 360 ; ++phi) { reg = EBRegionId (eta,phi) ; m_xtalRegionId[EBDetId::unhashIndex (eta*360+phi).rawId ()] = reg ; if (reg==-1) continue; m_xtalPositionInRegion[EBDetId::unhashIndex (eta*360+phi).rawId ()] = m_regions.at (reg) ; ++m_regions.at (reg); } }
int EcalEleCalibLooper::EBRegionId | ( | const int | etaXtl, |
const int | phiXtl | ||
) | const [private] |
Reg Id generator EB ----- for the barrel.
Definition at line 455 of file EcalEleCalibLooper.cc.
References EBregionCheck(), m_etaStart, m_etaWidth, m_phiEndEB, m_phiStartEB, and m_phiWidthEB.
Referenced by EBRegionDefinition().
{ if (EBregionCheck(etaXtl,phiXtl)) return -1; int phifake = m_phiStartEB; if (m_phiStartEB>m_phiEndEB) phifake = m_phiStartEB - 360; int Nphi = (m_phiEndEB-phifake)/m_phiWidthEB ; int etaI = (etaXtl-m_etaStart) / m_etaWidth ; int phiI = (phiXtl-m_phiStartEB) / m_phiWidthEB ; int regionNumEB = phiI + Nphi*etaI ; return (int) regionNumEB; }
int EcalEleCalibLooper::EBregionsNum | ( | ) | const [inline, private] |
DS number of regions in EB.
Definition at line 507 of file EcalEleCalibLooper.cc.
References m_etaEnd, m_etaStart, m_etaWidth, m_phiEndEB, m_phiStartEB, m_phiWidthEB, and phi.
Referenced by EBRegionDefinition(), EcalEleCalibLooper(), and EERegionDefinition().
{ int phi = m_phiStartEB; if (m_phiStartEB>m_phiEndEB) phi = m_phiStartEB - 360; return ( (m_etaEnd - m_etaStart)/m_etaWidth) * ( (m_phiEndEB - phi)/m_phiWidthEB) ; }
int EcalEleCalibLooper::EEregionCheck | ( | const int | ics, |
const int | ips | ||
) | const [private] |
returns zero if the coordinates are in the right place.
Definition at line 576 of file EcalEleCalibLooper.cc.
References degrees(), m_phiEndEE, m_phiStartEE, m_radEnd, m_radStart, phi, x, and detailsBasic3DVector::y.
Referenced by EERegionId().
{ int x = ics-50; int y = ips-50; double radius2 = x*x + y*y ; if (radius2 < 10*10) return 1; //center of the donut if (radius2 > 50*50) return 1; //outer part of the donut if (radius2 < m_radStart * m_radStart) return 2 ; if (radius2 >= m_radEnd * m_radEnd) return 2 ; double phi = atan2 (static_cast<double> (y),static_cast<double> (x)); phi = degrees (phi); if (phi < 0) phi += 360; if (m_phiStartEE < m_phiEndEE && phi > m_phiStartEE && phi < m_phiEndEE ) return 0; if (m_phiStartEE > m_phiEndEE && (phi > m_phiStartEE || phi < m_phiEndEE )) return 0; return 3; }
void EcalEleCalibLooper::EERegionDefinition | ( | ) | [private] |
Definition at line 539 of file EcalEleCalibLooper.cc.
References bsc_activity_cfg::EBnum, EBregionsNum(), bsc_activity_cfg::EEnum, EERegionId(), EEregionsNum(), h2_mapping_cfi::ics, m_regions, m_xtalPositionInRegion, m_xtalRegionId, DetId::rawId(), and EEDetId::validDetId().
Referenced by EcalEleCalibLooper().
{ // reset int EBnum=EBregionsNum(); int EEnum=EEregionsNum(); for (int it = 0 ; it < 2* EEnum ; ++it) m_regions.push_back (0) ; // loop sui xtl int reg=-1; for (int ics = 0 ; ics < 100 ; ++ics) for (int ips = 0 ; ips < 100 ; ++ips) { int ireg = EERegionId(ics, ips); if (ireg==-1) reg =-1; else reg = EBnum + ireg; if (EEDetId::validDetId (ics+1, ips+1, 1)) { m_xtalRegionId[EEDetId (ics+1, ips+1, 1).rawId ()] = reg ; if (reg==-1) continue; m_xtalPositionInRegion[EEDetId (ics+1, ips+1, 1).rawId ()] = m_regions.at (reg) ; ++m_regions.at(reg); } if (reg!=-1) reg += EEnum; if (EEDetId::validDetId (ics+1, ips+1, -1)) { m_xtalRegionId[EEDetId (ics+1, ips+1, -1).rawId ()] = reg ; if (reg==-1) continue; m_xtalPositionInRegion[EEDetId (ics+1, ips+1, -1).rawId ()] = m_regions.at (reg) ; ++m_regions.at (reg) ; } } }
int EcalEleCalibLooper::EERegionId | ( | const int | ics, |
const int | ips | ||
) | const [private] |
Gives the id of the region.
Definition at line 472 of file EcalEleCalibLooper.cc.
References degrees(), EEregionCheck(), m_phiEndEE, m_phiStartEE, m_phiWidthEE, m_radStart, m_radWidth, phi, CosmicsPD_Skims::radius, and mathSSE::sqrt().
Referenced by EERegionDefinition().
{ if (EEregionCheck(ics,ips)) return -1; int phifake = m_phiStartEE; if (m_phiStartEE>m_phiEndEE) phifake = m_phiStartEE - 360; double radius = (ics-50) * (ics-50) + (ips-50) * (ips-50) ; radius = sqrt (radius) ; int Nphi = (m_phiEndEE - phifake)/m_phiWidthEE ; double phi = atan2 (static_cast<double> (ips-50), static_cast<double> (ics-50)) ; phi = degrees (phi); if (phi < 0) phi += 360; int radI = static_cast<int> ((radius-m_radStart) / m_radWidth) ; int phiI = static_cast<int> ((m_phiEndEE-phi) / m_phiWidthEE) ; int regionNumEE = phiI + Nphi*radI ; return regionNumEE ; }
int EcalEleCalibLooper::EEregionsNum | ( | ) | const [inline, private] |
DS Number of regions in EE.
Definition at line 495 of file EcalEleCalibLooper.cc.
References m_phiEndEE, m_phiStartEE, m_phiWidthEE, m_radEnd, m_radStart, and m_radWidth.
Referenced by EcalEleCalibLooper(), and EERegionDefinition().
{ int phifake = m_phiStartEE; if (m_phiStartEE>m_phiEndEE) phifake = m_phiStartEE - 360; return ( (m_radEnd - m_radStart)/m_radWidth) * ( (m_phiEndEE - phifake)/m_phiWidthEE) ; }
void EcalEleCalibLooper::endOfJob | ( | ) | [virtual] |
LP endOfJob writes the coefficients in the xml format and exits
Reimplemented from edm::EDLooperBase.
Definition at line 365 of file EcalEleCalibLooper.cc.
References EcalBarrel, EcalEndcap, m_barrelCells, m_barrelMap, m_endcapCells, m_endcapMap, and calibXMLwriter::writeLine().
{ edm::LogInfo ("IML") << "[InvMatrixCalibLooper][endOfJob] saving calib coeffs" ; //Writes the coeffs calibXMLwriter barrelWriter (EcalBarrel); calibXMLwriter endcapWriter (EcalEndcap); for (std::vector<DetId>::const_iterator barrelIt = m_barrelCells.begin (); barrelIt!=m_barrelCells.end (); ++barrelIt) { EBDetId eb (*barrelIt); barrelWriter.writeLine (eb,m_barrelMap[*barrelIt]); } for (std::vector<DetId>::const_iterator endcapIt = m_endcapCells.begin (); endcapIt!=m_endcapCells.end (); ++endcapIt) { EEDetId ee (*endcapIt); endcapWriter.writeLine (ee,m_endcapMap[*endcapIt]); } edm::LogInfo ("IML") << "[InvMatrixCalibLooper][endOfJob] Exiting" ; }
edm::EDLooper::Status EcalEleCalibLooper::endOfLoop | ( | const edm::EventSetup & | dumb, |
unsigned int | iCounter | ||
) | [virtual] |
EndOfLoop Return kContinue if there's still another loop to be done; otherwise stops returnig kStop; Takes the coefficients solving the calibBlock;
Implements edm::EDLooperBase.
Definition at line 286 of file EcalEleCalibLooper.cc.
References lut2db_cfg::filename, EBDetId::ieta(), getHLTprescales::index, EBDetId::iphi(), EEDetId::ix(), EEDetId::iy(), edm::EDLooperBase::kContinue, edm::EDLooperBase::kStop, m_barrelCells, m_barrelMap, m_EcalCalibBlocks, m_endcapCells, m_endcapMap, m_loops, m_maxCoeff, m_minCoeff, m_usingBlockSolver, m_xtalPositionInRegion, m_xtalRegionId, and EEDetId::zside().
{ edm::LogInfo ("IML") << "[InvMatrixCalibLooper][endOfLoop] entering..." ; for (std::vector<VEcalCalibBlock *>::iterator calibBlock = m_EcalCalibBlocks.begin (); calibBlock!=m_EcalCalibBlocks.end (); ++calibBlock) (*calibBlock)->solve (m_usingBlockSolver, m_minCoeff,m_maxCoeff); TH1F * EBcoeffEnd = new TH1F ("EBRegion","EBRegion",100,0.5,2.1) ; TH2F * EBcoeffMap = new TH2F ("EBcoeff","EBcoeff",171,-85,85,360,1,361); TH1F * EEPcoeffEnd = new TH1F ("EEPRegion", "EEPRegion",100,0.5,2.1); TH1F * EEMcoeffEnd = new TH1F ("EEMRegion", "EEMRegion",100,0.5,2.1); TH2F * EEPcoeffMap = new TH2F ("EEPcoeffMap","EEPcoeffMap",101,1,101,101,0,101); TH2F * EEMcoeffMap = new TH2F ("EEMcoeffMap","EEMcoeffMap",101,1,101,101,0,101); //loop over the barrel xtals to get the coeffs for (std::vector<DetId>::const_iterator barrelIt=m_barrelCells.begin(); barrelIt!=m_barrelCells.end();++barrelIt) { EBDetId ee (*barrelIt); int index= barrelIt->rawId(); if(m_xtalRegionId[index]==-1)continue; m_barrelMap[*barrelIt] *= m_EcalCalibBlocks.at(m_xtalRegionId[index])->at(m_xtalPositionInRegion[index]); EBcoeffEnd->Fill(m_barrelMap[*barrelIt]); EBcoeffMap->Fill(ee.ieta(),ee.iphi(),m_barrelMap[*barrelIt]); } //PG loop over phi // loop over the EndCap to get the recalib coefficients for(std::vector<DetId>::const_iterator endcapIt=m_endcapCells.begin(); endcapIt!=m_endcapCells.end();++endcapIt) { EEDetId ee (*endcapIt); int index =endcapIt->rawId(); if (ee.zside()>0) { if (m_xtalRegionId[index]==-1) continue ; m_endcapMap[*endcapIt] *= m_EcalCalibBlocks.at (m_xtalRegionId[index])->at (m_xtalPositionInRegion[index]); EEPcoeffEnd->Fill (m_endcapMap[*endcapIt]) ; EEPcoeffMap->Fill (ee.ix(),ee.iy(),m_endcapMap[*endcapIt]) ; } else { m_endcapMap[*endcapIt] *= m_EcalCalibBlocks.at (m_xtalRegionId[index])->at (m_xtalPositionInRegion[index]); EEMcoeffEnd->Fill (m_endcapMap[*endcapIt]) ; EEMcoeffMap->Fill (ee.ix(),ee.iy(),m_endcapMap[*endcapIt]) ; } } // loop over the EndCap to get the recalib coefficients edm::LogInfo ("IML") << "[InvMatrixCalibLooper][endOfLoop] End of endOfLoop" ; char filename[80]; sprintf(filename,"coeffs%d.root",iCounter); TFile zout (filename, "recreate"); EBcoeffEnd->Write () ; EBcoeffMap->Write () ; EEPcoeffEnd->Write () ; EEPcoeffMap->Write () ; EEMcoeffEnd->Write () ; EEMcoeffMap->Write () ; zout.Close () ; delete EBcoeffEnd; delete EBcoeffMap; delete EEPcoeffEnd; delete EEMcoeffEnd; delete EEPcoeffMap; delete EEMcoeffMap; if (iCounter < m_loops-1 ) return kContinue ; else return kStop; }
int EcalEleCalibLooper::etaShifter | ( | const int | etaOld | ) | const [private] |
LP Change the coordinate system.
Definition at line 600 of file EcalEleCalibLooper.cc.
{ if (etaOld < 0) return etaOld + 85; else if (etaOld > 0) return etaOld + 84; assert(0!=etaOld); // etaOld = 0, apparently not a foreseen value, so fail return 999; // dummy statement to silence compiler warning }
double EcalEleCalibLooper::giveLimit | ( | int | degrees | ) | [private] |
copes with the infinitives of the tangent
Definition at line 431 of file EcalEleCalibLooper.cc.
References radiants(), and funct::tan().
void EcalEleCalibLooper::startingNewLoop | ( | unsigned int | ciclo | ) | [virtual] |
startingNewLoop empties the map of the calibBlock so that it can be filled
Implements edm::EDLooperBase.
Definition at line 170 of file EcalEleCalibLooper.cc.
References m_EcalCalibBlocks, and m_xtalNumOfHits.
{ edm::LogInfo ("IML") << "[InvMatrixCalibLooper][Start] entering loop " << ciclo; for (std::vector<VEcalCalibBlock *>::iterator calibBlock = m_EcalCalibBlocks.begin () ; calibBlock != m_EcalCalibBlocks.end () ; ++calibBlock) (*calibBlock)->reset (); for (std::map<int,int>::iterator it= m_xtalNumOfHits.begin(); it!=m_xtalNumOfHits.end(); ++it) it->second = 0 ; return ; }
bool EcalEleCalibLooper::isfirstcall_ [private] |
Definition at line 145 of file EcalEleCalibLooper.h.
Referenced by beginOfJob(), and duringLoop().
EcalBarrel Input Collection name.
Definition at line 70 of file EcalEleCalibLooper.h.
Referenced by duringLoop().
std::vector<DetId> EcalEleCalibLooper::m_barrelCells [private] |
Definition at line 138 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), endOfJob(), and endOfLoop().
the maps of recalib coeffs
Definition at line 121 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), EcalEleCalibLooper(), endOfJob(), and endOfLoop().
std::vector<VEcalCalibBlock *> EcalEleCalibLooper::m_EcalCalibBlocks [private] |
single blocks calibrators
Definition at line 108 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), EcalEleCalibLooper(), endOfLoop(), startingNewLoop(), and ~EcalEleCalibLooper().
To take the electrons.
Definition at line 127 of file EcalEleCalibLooper.h.
Referenced by duringLoop().
EcalEndcap Input Collection name.
Definition at line 72 of file EcalEleCalibLooper.h.
Referenced by duringLoop().
std::vector<DetId> EcalEleCalibLooper::m_endcapCells [private] |
Definition at line 139 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), endOfJob(), and endOfLoop().
Definition at line 122 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), EcalEleCalibLooper(), endOfJob(), and endOfLoop().
int EcalEleCalibLooper::m_etaEnd [private] |
eta end of the region of interest
Definition at line 90 of file EcalEleCalibLooper.h.
Referenced by EBregionCheck(), EBregionsNum(), and EcalEleCalibLooper().
int EcalEleCalibLooper::m_etaStart [private] |
phi size of the additive border to the sub-matrix
eta start of the region of interest
Definition at line 88 of file EcalEleCalibLooper.h.
Referenced by EBregionCheck(), EBRegionId(), EBregionsNum(), and EcalEleCalibLooper().
int EcalEleCalibLooper::m_etaWidth [private] |
eta size of the sub-matrix
Definition at line 79 of file EcalEleCalibLooper.h.
Referenced by EBRegionId(), EBregionsNum(), and EcalEleCalibLooper().
unsigned int EcalEleCalibLooper::m_loops [private] |
DS sets the number of loops to do.
Definition at line 125 of file EcalEleCalibLooper.h.
Referenced by endOfLoop().
VFillMap* EcalEleCalibLooper::m_MapFiller [private] |
Definition at line 129 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), and EcalEleCalibLooper().
double EcalEleCalibLooper::m_maxCoeff [private] |
maximum coefficient accepted (RAW)
Definition at line 116 of file EcalEleCalibLooper.h.
Referenced by endOfLoop().
double EcalEleCalibLooper::m_maxEnergyPerCrystal [private] |
maximum energy per crystal cut
Definition at line 112 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper().
int EcalEleCalibLooper::m_maxSelectedNumPerXtal [private] |
maximum number of events per crystal
Definition at line 105 of file EcalEleCalibLooper.h.
Referenced by duringLoop().
double EcalEleCalibLooper::m_minCoeff [private] |
minimum coefficient accepted (RAW)
Definition at line 114 of file EcalEleCalibLooper.h.
Referenced by endOfLoop().
double EcalEleCalibLooper::m_minEnergyPerCrystal [private] |
minimum energy per crystal cut
Definition at line 110 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper().
int EcalEleCalibLooper::m_phiEndEB [private] |
phi end of the region of interest
Definition at line 94 of file EcalEleCalibLooper.h.
Referenced by EBregionCheck(), EBRegionId(), and EBregionsNum().
int EcalEleCalibLooper::m_phiEndEE [private] |
Definition at line 101 of file EcalEleCalibLooper.h.
Referenced by EEregionCheck(), EERegionId(), and EEregionsNum().
int EcalEleCalibLooper::m_phiStartEB [private] |
phi start of the region of interest
Definition at line 92 of file EcalEleCalibLooper.h.
Referenced by EBregionCheck(), EBRegionId(), and EBregionsNum().
int EcalEleCalibLooper::m_phiStartEE [private] |
Definition at line 100 of file EcalEleCalibLooper.h.
Referenced by EEregionCheck(), EERegionId(), and EEregionsNum().
int EcalEleCalibLooper::m_phiWidthEB [private] |
eta size of the additive border to the sub-matrix
phi size of the sub-matrix
Definition at line 83 of file EcalEleCalibLooper.h.
Referenced by EBRegionId(), and EBregionsNum().
int EcalEleCalibLooper::m_phiWidthEE [private] |
Definition at line 102 of file EcalEleCalibLooper.h.
Referenced by EERegionId(), and EEregionsNum().
int EcalEleCalibLooper::m_radEnd [private] |
Definition at line 97 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper(), EEregionCheck(), and EEregionsNum().
int EcalEleCalibLooper::m_radStart [private] |
DS For the EE.
Definition at line 96 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper(), EEregionCheck(), EERegionId(), and EEregionsNum().
int EcalEleCalibLooper::m_radWidth [private] |
Definition at line 98 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper(), EERegionId(), and EEregionsNum().
int EcalEleCalibLooper::m_recoWindowSidex [private] |
reconstruction window size
Definition at line 75 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper().
int EcalEleCalibLooper::m_recoWindowSidey [private] |
Definition at line 76 of file EcalEleCalibLooper.h.
Referenced by EcalEleCalibLooper().
std::vector<int> EcalEleCalibLooper::m_regions [private] |
Definition at line 136 of file EcalEleCalibLooper.h.
Referenced by EBRegionDefinition(), EcalEleCalibLooper(), and EERegionDefinition().
int EcalEleCalibLooper::m_usingBlockSolver [private] |
to exclude the blocksolver
Definition at line 118 of file EcalEleCalibLooper.h.
Referenced by endOfLoop().
std::map<int,int> EcalEleCalibLooper::m_xtalNumOfHits [private] |
Definition at line 143 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), and startingNewLoop().
std::map<int,int> EcalEleCalibLooper::m_xtalPositionInRegion [private] |
Definition at line 142 of file EcalEleCalibLooper.h.
Referenced by EBRegionDefinition(), EcalEleCalibLooper(), EERegionDefinition(), and endOfLoop().
std::map<int,int> EcalEleCalibLooper::m_xtalRegionId [private] |
Definition at line 141 of file EcalEleCalibLooper.h.
Referenced by duringLoop(), EBRegionDefinition(), EcalEleCalibLooper(), EERegionDefinition(), and endOfLoop().