d9/d42/HcalDeterministicFit_8h_source.html

 #ifndef HcalDeterministicFit_h
 #define HcalDeterministicFit_h 1

 #include <typeinfo>
 #include <vector>

 #include "CalibCalorimetry/HcalAlgos/interface/HcalTimeSlew.h"
 #include "RecoLocalCalo/HcalRecAlgos/interface/PedestalSub.h"

 #include "DataFormats/HcalDetId/interface/HcalDetId.h"
 #include "DataFormats/HcalRecHit/interface/HBHEChannelInfo.h"
 #include "CalibCalorimetry/HcalAlgos/interface/HcalPulseShapes.h"
 #include "CalibFormats/HcalObjects/interface/HcalCoder.h"
 #include "CalibFormats/HcalObjects/interface/HcalCalibrations.h"

 class HcalDeterministicFit {
  public:
   HcalDeterministicFit();
   ~HcalDeterministicFit();

   void init(HcalTimeSlew::ParaSource tsParam, HcalTimeSlew::BiasSetting bias, bool iApplyTimeSlew, PedestalSub pedSubFxn_, std::vector<double> pars, double respCorr);

   void phase1Apply(const HBHEChannelInfo& channelData,
            float& reconstructedEnergy,
            float& reconstructedTime) const;

   // This is the CMSSW Implementation of the apply function
   template<class Digi>
   void apply(const CaloSamples & cs, const std::vector<int> & capidvec, const HcalCalibrations & calibs, const Digi & digi, double& ampl, float &time) const;
   void getLandauFrac(float tStart, float tEnd, float &sum) const;

  private:
   HcalTimeSlew::ParaSource fTimeSlew;
   HcalTimeSlew::BiasSetting fTimeSlewBias;
   PedestalSub fPedestalSubFxn_;
   bool applyTimeSlew_;

   double fpars[9];
   double frespCorr;

   static constexpr int HcalRegion[2] = {16, 17};
   static constexpr int tsWidth = 25;
   static constexpr float negThresh[2] = {-3., 15.};
   static constexpr float invGpar[3] = {-13.11, 11.29, 5.133};
   static constexpr float rCorr[2] = {0.95, 0.95};
   static constexpr float rCorrSiPM[2] = {1., 1.};
   static constexpr float landauFrac[] = {0, 7.6377e-05, 0.000418655, 0.00153692, 0.00436844, 0.0102076,
   0.0204177, 0.0360559, 0.057596, 0.0848493, 0.117069, 0.153152, 0.191858, 0.23198, 0.272461, 0.312438,
   0.351262, 0.388476, 0.423788, 0.457036, 0.488159, 0.517167, 0.54412, 0.569112, 0.592254, 0.613668,
   0.633402, 0.651391, 0.667242, 0.680131, 0.688868, 0.692188, 0.689122, 0.67928, 0.662924, 0.64087,
   0.614282, 0.584457, 0.552651, 0.51997, 0.487317, 0.455378, 0.424647, 0.395445, 0.367963, 0.342288,
   0.318433, 0.29636, 0.275994, 0.257243, 0.24, 0.224155, 0.2096, 0.196227, 0.183937, 0.172635,
   0.162232, 0.15265, 0.143813, 0.135656, 0.128117, 0.12114, 0.114677, 0.108681, 0.103113, 0.0979354,
   0.0931145, 0.0886206, 0.0844264, 0.0805074, 0.0768411, 0.0734075, 0.0701881, 0.0671664, 0.0643271,
   0.0616564, 0.0591418, 0.0567718, 0.054536, 0.0524247, 0.0504292, 0.0485414, 0.046754, 0.0450602,
   0.0434538, 0.041929, 0.0404806, 0.0391037, 0.0377937, 0.0365465, 0.0353583, 0.0342255, 0.0331447,
   0.032113, 0.0311274, 0.0301854, 0.0292843, 0.0284221, 0.0275964, 0.0268053, 0.0253052, 0.0238536,
   0.0224483, 0.0210872, 0.0197684, 0.0184899, 0.01725, 0.0160471, 0.0148795, 0.0137457, 0.0126445,
   0.0115743, 0.0105341, 0.00952249, 0.00853844, 0.00758086, 0.00664871,0.00574103, 0.00485689, 0.00399541,
   0.00315576, 0.00233713, 0.00153878, 0.000759962, 0 };
 };

 template<class Digi>
 void HcalDeterministicFit::apply(const CaloSamples & cs, const std::vector<int> & capidvec, const HcalCalibrations & calibs, const Digi & digi, double & reconstructedEnergy, float & reconstructedTime) const {
   std::vector<double> corrCharge;
   std::vector<double> inputCharge;
   std::vector<double> inputPedestal;
   double gainCorr = 0;
   double respCorr = 0;

   for(int ip=0; ip<cs.size(); ip++){
     const int capid = capidvec[ip];
     double charge = cs[ip];
     double ped = calibs.pedestal(capid);
     double gain = calibs.respcorrgain(capid);
     gainCorr = gain;
     inputCharge.push_back(charge);
     inputPedestal.push_back(ped);
   }

   fPedestalSubFxn_.calculate(inputCharge, inputPedestal, corrCharge);

   const HcalDetId& cell = digi.id();
   double fpar0, fpar1, fpar2;
   if(std::abs(cell.ieta())<HcalRegion[0]){
     fpar0 = fpars[0];
     fpar1 = fpars[1];
     fpar2 = fpars[2];
   }else if(std::abs(cell.ieta())==HcalRegion[0]||std::abs(cell.ieta())==HcalRegion[1]){
     fpar0 = fpars[3];
     fpar1 = fpars[4];
     fpar2 = fpars[5];
   }else{
     fpar0 = fpars[6];
     fpar1 = fpars[7];
     fpar2 = fpars[8];
   }

   if (fTimeSlew==0)respCorr=1.0;
   else if (fTimeSlew==1)respCorr=rCorr[0];
   else if (fTimeSlew==2)respCorr=rCorr[1];
   else if (fTimeSlew==3)respCorr=frespCorr;

   float tsShift3=HcalTimeSlew::delay(inputCharge[3], fTimeSlew, fTimeSlewBias, fpar0, fpar1 ,fpar2);
   float tsShift4=HcalTimeSlew::delay(inputCharge[4], fTimeSlew, fTimeSlewBias, fpar0, fpar1 ,fpar2);
   float tsShift5=HcalTimeSlew::delay(inputCharge[5], fTimeSlew, fTimeSlewBias, fpar0, fpar1 ,fpar2);

   float i3=0;
   getLandauFrac(-tsShift3,-tsShift3+tsWidth,i3);
   float n3=0;
   getLandauFrac(-tsShift3+tsWidth,-tsShift3+tsWidth*2,n3);
   float nn3=0;
   getLandauFrac(-tsShift3+tsWidth*2,-tsShift3+tsWidth*3,nn3);

   float i4=0;
   getLandauFrac(-tsShift4,-tsShift4+tsWidth,i4);
   float n4=0;
   getLandauFrac(-tsShift4+tsWidth,-tsShift4+tsWidth*2,n4);

   float i5=0;
   getLandauFrac(-tsShift5,-tsShift5+tsWidth,i5);
   float n5=0;
   getLandauFrac(-tsShift5+tsWidth,-tsShift5+tsWidth*2,n5);

   float ch3=0;
   float ch4=0;
   float ch5=0;

   if (i3 != 0 && i4 != 0 && i5 != 0) {

     ch3=corrCharge[3]/i3;
     ch4=(i3*corrCharge[4]-n3*corrCharge[3])/(i3*i4);
     ch5=(n3*n4*corrCharge[3]-i4*nn3*corrCharge[3]-i3*n4*corrCharge[4]+i3*i4*corrCharge[5])/(i3*i4*i5);

     if (ch3<negThresh[0]) {
       ch3=negThresh[0];
       ch4=corrCharge[4]/i4;
       ch5=(i4*corrCharge[5]-n4*corrCharge[4])/(i4*i5);
     }
     if (ch5<negThresh[0] && ch4>negThresh[1]) {
       double ratio = (corrCharge[4]-ch3*i3)/(corrCharge[5]-negThresh[0]*i5);
       if (ratio < 5 && ratio > 0.5) {
         double invG = invGpar[0]+invGpar[1]*std::sqrt(2*std::log(invGpar[2]/ratio));
         float iG=0;
         getLandauFrac(-invG,-invG+tsWidth,iG);
         if (iG != 0 ) {
       ch4=(corrCharge[4]-ch3*n3)/(iG);
       tsShift4=invG;
     }
       }
     }
   }

   if (ch4<1) {
     ch4=0;
   }

   double ampl=ch4*gainCorr*respCorr;
   reconstructedEnergy=ampl;
   reconstructedTime=tsShift4;
 }


 #endif // HLTAnalyzer_h
PedestalSub.h

HBHEChannelInfo
Definition: HBHEChannelInfo.h:14

HcalDeterministicFit::tsWidth
static constexpr int tsWidth
Definition: HcalDeterministicFit.h:42

HcalCalibrations::respcorrgain
double respcorrgain(int fCapId) const
get response corrected gain for capid=0..3
Definition: HcalCalibrations.h:16

fwrapper::cs
auto_ptr< ClusterSequence > cs
Definition: fastjetfortran_madfks.cc:45

HcalPulseShapes.h

particleFlowDisplacedVertex_cfi.ratio
ratio
Definition: particleFlowDisplacedVertex_cfi.py:93

HcalDeterministicFit::rCorr
static constexpr float rCorr[2]
Definition: HcalDeterministicFit.h:45

HcalDeterministicFit::frespCorr
double frespCorr
Definition: HcalDeterministicFit.h:39

HcalDeterministicFit::~HcalDeterministicFit
~HcalDeterministicFit()
Definition: HcalDeterministicFit.cc:17

HcalDeterministicFit::rCorrSiPM
static constexpr float rCorrSiPM[2]
Definition: HcalDeterministicFit.h:46

HcalDeterministicFit::HcalRegion
static constexpr int HcalRegion[2]
Definition: HcalDeterministicFit.h:41

HcalDeterministicFit::landauFrac
static constexpr float landauFrac[]
Definition: HcalDeterministicFit.h:47

HcalDeterministicFit::phase1Apply
void phase1Apply(const HBHEChannelInfo &channelData, float &reconstructedEnergy, float &reconstructedTime) const
Definition: HcalDeterministicFit.cc:48

HBHEChannelInfo.h

HcalCalibrations.h

HcalCalibrations
Definition: HcalCalibrations.h:9

HcalCalibrations::pedestal
double pedestal(int fCapId) const
get pedestal for capid=0..3
Definition: HcalCalibrations.h:20

HcalTimeSlew::ParaSource
ParaSource
Definition: HcalTimeSlew.h:20

matching::Digi
std::tuple< unsigned int, int, int, DigiType, int, int, int, float > Digi
Definition: GenericDigi.h:30

constexpr
#define constexpr

CaloSamples
Definition: CaloSamples.h:14

HcalDeterministicFit::fTimeSlew
HcalTimeSlew::ParaSource fTimeSlew
Definition: HcalDeterministicFit.h:33

HcalDeterministicFit::fPedestalSubFxn_
PedestalSub fPedestalSubFxn_
Definition: HcalDeterministicFit.h:35

HcalDeterministicFit::applyTimeSlew_
bool applyTimeSlew_
Definition: HcalDeterministicFit.h:36

HcalDetId
Definition: HcalDetId.h:12

HcalDetId.h

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:18

PedestalSub
Definition: PedestalSub.h:7

HcalTimeSlew::BiasSetting
BiasSetting
Definition: HcalTimeSlew.h:21

HcalDetId::ieta
int ieta() const
get the cell ieta
Definition: HcalDetId.h:56

funct::abs
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

HcalDeterministicFit::getLandauFrac
void getLandauFrac(float tStart, float tEnd, float &sum) const
Definition: HcalDeterministicFit.cc:38

HcalDeterministicFit
Definition: HcalDeterministicFit.h:16

ALCARECOTkAlJpsiMuMu_cff.charge
charge
Definition: ALCARECOTkAlJpsiMuMu_cff.py:47

ntuplemaker.time
time
Definition: ntuplemaker.py:308

muonCSCDigis_cfi.gain
gain
Definition: muonCSCDigis_cfi.py:36

PedestalSub::calculate
void calculate(const std::vector< double > &inputCharge, const std::vector< double > &inputPedestal, std::vector< double > &corrCharge) const
Definition: PedestalSub.cc:20

HcalDeterministicFit::apply
void apply(const CaloSamples &cs, const std::vector< int > &capidvec, const HcalCalibrations &calibs, const Digi &digi, double &ampl, float &time) const
Definition: HcalDeterministicFit.h:64

CaloSamples::size
int size() const
get the size
Definition: CaloSamples.h:24

HcalDeterministicFit::init
void init(HcalTimeSlew::ParaSource tsParam, HcalTimeSlew::BiasSetting bias, bool iApplyTimeSlew, PedestalSub pedSubFxn_, std::vector< double > pars, double respCorr)
Definition: HcalDeterministicFit.cc:20

cmsBatch.log
log
Definition: cmsBatch.py:341

HcalDeterministicFit::negThresh
static constexpr float negThresh[2]
Definition: HcalDeterministicFit.h:43

HcalCoder.h

HcalDeterministicFit::fpars
double fpars[9]
Definition: HcalDeterministicFit.h:38

HcalDeterministicFit::HcalDeterministicFit
HcalDeterministicFit()
Definition: HcalDeterministicFit.cc:14

HcalDeterministicFit::fTimeSlewBias
HcalTimeSlew::BiasSetting fTimeSlewBias
Definition: HcalDeterministicFit.h:34

HcalTimeSlew.h

HcalTimeSlew::delay
static double delay(double fC, BiasSetting bias=Medium)
Returns the amount (ns) by which a pulse of the given number of fC will be delayed by the timeslew ef...
Definition: HcalTimeSlew.cc:16

HcalDeterministicFit::invGpar
static constexpr float invGpar[3]
Definition: HcalDeterministicFit.h:44