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Public Member Functions | Static Public Attributes | Private Member Functions | Private Attributes

CSCTFPtLUT Class Reference

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#include <CSCTFPtLUT.h>

List of all members.

Public Member Functions

 CSCTFPtLUT (const edm::EventSetup &c)
 KK.
 CSCTFPtLUT (const edm::ParameterSet &, const L1MuTriggerScales *scales, const L1MuTriggerPtScale *ptScale)
 CSCTFPtLUT (const CSCTFPtLUT &)
CSCTFPtLUToperator= (const CSCTFPtLUT &)
ptdat Pt (const unsigned &) const
ptdat Pt (const unsigned &delta_phi_12, const unsigned &track_eta, const unsigned &track_mode, const unsigned &track_fr, const unsigned &delta_phi_sign) const
ptdat Pt (const unsigned &delta_phi_12, const unsigned &delta_phi23, const unsigned &track_eta, const unsigned &track_mode, const unsigned &track_fr, const unsigned &delta_phi_sign) const
ptdat Pt (const ptadd &) const
 ~CSCTFPtLUT ()

Static Public Attributes

static const int dEtaCut_High_A [24] = {3,3,4,7,3,2,4,7,5,5,5,7,2,2,2,2,3,3,3,3,2,2,2,2}
static const int dEtaCut_High_B [24] = {3,3,4,7,3,3,5,7,6,6,6,7,2,2,3,3,3,3,3,3,3,3,3,2}
static const int dEtaCut_High_C [24] = {4,4,5,7,4,3,6,7,7,7,7,7,3,3,3,3,4,4,4,4,3,3,3,3}
static const int dEtaCut_Low [24] = {2,2,2,7,2,1,2,7,3,3,3,7,1,1,1,1,2,2,2,2,1,1,1,1}
static const int dEtaCut_Mid [24] = {2,2,3,7,2,2,3,7,4,4,4,7,2,2,2,2,2,2,2,2,2,2,2,2}
static const int dEtaCut_Open [24] = {7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7}
static const int dPhiNLBMap_5bit [32]
static const int dPhiNLBMap_7bit [128]
static const int dPhiNLBMap_8bit [256]
static const int getPtbyMLH = 0xFFFF

Private Member Functions

ptdat calcPt (const ptadd &) const
void readLUT ()
unsigned trackQuality (const unsigned &eta, const unsigned &mode, const unsigned &fr) const

Private Attributes

bool isBeamStartConf
bool isBinary
unsigned lowQualityFlag
ptdatpt_lut
edm::FileInPath pt_lut_file
unsigned pt_method
CSCTFPtMethods ptMethods
bool read_pt_lut_es
bool read_pt_lut_file
const L1MuCSCPtLuttheL1MuCSCPtLut_
const L1MuTriggerPtScaletrigger_ptscale
const L1MuTriggerScalestrigger_scale

Detailed Description

KK.

Definition at line 16 of file CSCTFPtLUT.h.


Constructor & Destructor Documentation

CSCTFPtLUT::CSCTFPtLUT ( const edm::EventSetup c)

KK.

Definition at line 72 of file CSCTFPtLUT.cc.

References edm::EventSetup::get(), isBeamStartConf, lowQualityFlag, edm::ESHandle< T >::product(), pt_method, ptMethods, theL1MuCSCPtLut_, trigger_ptscale, and trigger_scale.

    : read_pt_lut_es(true),
      read_pt_lut_file(false),
      isBinary(false)
{
        pt_method = 32;

        lowQualityFlag = 4;
        isBeamStartConf = true;

        edm::ESHandle<L1MuCSCPtLut> ptLUT;
        es.get<L1MuCSCPtLutRcd>().get(ptLUT);
        theL1MuCSCPtLut_ = ptLUT.product();

        //std::cout << "theL1MuCSCPtLut_ pointer is "
        //          << theL1MuCSCPtLut_
        //          << std::endl;

        edm::ESHandle< L1MuTriggerScales > scales ;
        es.get< L1MuTriggerScalesRcd >().get( scales ) ;
        trigger_scale = scales.product() ;

        edm::ESHandle< L1MuTriggerPtScale > ptScale ;
        es.get< L1MuTriggerPtScaleRcd >().get( ptScale ) ;
        trigger_ptscale = ptScale.product() ;

        ptMethods = CSCTFPtMethods( ptScale.product() ) ;
 
}
CSCTFPtLUT::CSCTFPtLUT ( const edm::ParameterSet pset,
const L1MuTriggerScales scales,
const L1MuTriggerPtScale ptScale 
)

Definition at line 103 of file CSCTFPtLUT.cc.

References edm::FileInPath::fullPath(), edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), isBeamStartConf, isBinary, lowQualityFlag, pt_lut, pt_lut_file, pt_method, read_pt_lut_file, and readLUT().

  : trigger_scale( scales ),
    trigger_ptscale( ptScale ),
    ptMethods( ptScale ),
    read_pt_lut_es(false),
    read_pt_lut_file(false),
    isBinary(false)
{

  read_pt_lut_file = pset.getParameter<bool>("ReadPtLUT");
  if(read_pt_lut_file)
    {
      // if read from file, then need to set extra variables
      pt_lut_file = pset.getParameter<edm::FileInPath>("PtLUTFile");
      isBinary = pset.getParameter<bool>("isBinary");

      edm::LogInfo("CSCTFPtLUT::CSCTFPtLUT") << "Reading file: "
                                             << pt_lut_file.fullPath().c_str()
                                             << " isBinary?(1/0): "
                                             << isBinary;
    }

  // Determine the pt assignment method to use
  // 1 - Darin's parameterization method
  // 2 - Cathy Yeh's chi-square minimization method
  // 3 - Hybrid
  // 4 - Anna's parameterization method
  // 5 - Anna's parameterization method 
         //with improvments at ME1/1a: find max pt for 3 links hypothesis
  // 11 - Anna's: for fw 20101011 <- 2011 data taking <- not valide any more
  // 12 - Anna's: for fw 20101011 <- 2011 data taking <- not valide any more
          //with improvments at ME1/1a: find max pt for 3 links hypothesis
  // 21 - Anna's: for fw 20110118 and up, curves with data 2010 <- 2011 data taking
  // 22 - Anna's: for fw 20110118 and up, curves with data 2010 <- 2011 data taking
          //with improvments at ME1/1a: find max pt for 3 links hypothesis
  // 23 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
  // 24 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
          //with improvments at ME1/1a: find max pt for 3 links hypothesis
  //25 and 26 like 23 and 24 correspondenly but fix high pt assignment in DT-CSC region
  // 25 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
  // 26 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
          //with improvments at ME1/1a: find max pt for 3 links hypothesis
  // change Quality: Q = 3 for mode 5, Quility = 2 for mode = 8, 9, 10 at eta = 1.6-1.8   
  // 27 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
  // 28 - Anna's: for fw 20110118 and up, curves with MC like method 4 <- 2011 data taking
          //with improvments at ME1/1a: find max pt for 3 links hypothesis
  // 29 - Bobby's medium Quality: using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning. 
  // 33 - Bobby's medium Quality: using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning. No max pt at eta > 2.1 
  // 30 - Bobby's loose Quality: using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning. 
  // 31 - Bobby's tight Quality: using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning. 
  // 32 - Bobby's medium Quality+ {tight only mode5 at eta > 2.1}: using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning. 
  pt_method = pset.getUntrackedParameter<unsigned>("PtMethod",32);
  //std::cout << "pt_method from pset " << std::endl; 
  // what does this mean???
  lowQualityFlag = pset.getUntrackedParameter<unsigned>("LowQualityFlag",4);

  if(read_pt_lut_file)
    {
      pt_lut = new ptdat[1<<21];
      readLUT();
    }

  isBeamStartConf = pset.getUntrackedParameter<bool>("isBeamStartConf", true);
  
}
CSCTFPtLUT::CSCTFPtLUT ( const CSCTFPtLUT )
CSCTFPtLUT::~CSCTFPtLUT ( ) [inline]

Definition at line 28 of file CSCTFPtLUT.h.

{}

Member Function Documentation

ptdat CSCTFPtLUT::calcPt ( const ptadd address) const [private]

Definition at line 232 of file CSCTFPtLUT.cc.

References DeDxDiscriminatorTools::charge(), gather_cfg::cout, dEtaCut_High_A, dEtaCut_High_B, dEtaCut_High_C, dEtaCut_Low, dEtaCut_Mid, dEtaCut_Open, dPhiNLBMap_5bit, dPhiNLBMap_7bit, dPhiNLBMap_8bit, eta(), L1MuScale::getLowEdge(), L1MuScale::getPacked(), getPtbyMLH, L1MuTriggerPtScale::getPtScale(), L1MuTriggerScales::getRegionalEtaScale(), i, getHLTprescales::index, isBeamStartConf, max(), alignBH_cfg::mode, Pi, CSCTFPtMethods::Pt2Stn(), CSCTFPtMethods::Pt2Stn2010(), CSCTFPtMethods::Pt2Stn2011(), CSCTFPtMethods::Pt2Stn2012(), CSCTFPtMethods::Pt2StnChiSq(), CSCTFPtMethods::Pt2StnHybrid(), CSCTFPtMethods::Pt3Stn(), CSCTFPtMethods::Pt3Stn2010(), CSCTFPtMethods::Pt3Stn2011(), CSCTFPtMethods::Pt3Stn2012(), CSCTFPtMethods::Pt3Stn2012_DT(), CSCTFPtMethods::Pt3StnChiSq(), CSCTFPtMethods::Pt3StnHybrid(), pt_method, ptMethods, query::result, CSCTFConstants::SECTOR_RAD, trackQuality(), trigger_ptscale, and trigger_scale.

Referenced by Pt().

{
  ptdat result;

  double Pi  = acos(-1.);
  float etaR = 0, ptR_front = 0, ptR_rear = 0, dphi12R = 0, dphi23R = 0;
  int charge12, charge23;
  unsigned type, mode, eta, fr, quality, charge, absPhi12, absPhi23;

  mode = address.track_mode;
   
  int usedetaCUT = true;
  // Chose Eta cut tightness. 1=tightest, 2=moderate, 3=loose, 4=very loose, 5=extremely loose, 6=open

  // modes 6, 7, 13
  int EtaCutLevel_1 = 2;
  int dEtaCut_1[24];
  
  for (int i=0;i<24;i++)
    {
      dEtaCut_1[i] = 10;
      if (EtaCutLevel_1 == 1)
        dEtaCut_1[i] = dEtaCut_Low[i];
      else if (EtaCutLevel_1 == 2)
        dEtaCut_1[i] = dEtaCut_Mid[i];
      else if (EtaCutLevel_1 == 3)
        dEtaCut_1[i] = dEtaCut_High_A[i];
      else if (EtaCutLevel_1 == 4)
        dEtaCut_1[i] = dEtaCut_High_B[i];
      else if (EtaCutLevel_1 == 5)
        dEtaCut_1[i] = dEtaCut_High_C[i];
      else if (EtaCutLevel_1 == 6)
        dEtaCut_1[i] = dEtaCut_Open[i];
    }
  // modes 8, 9, 10
  int EtaCutLevel_2 = 2;
  int dEtaCut_2[24];
  
  for (int i=0;i<24;i++)
    {
      dEtaCut_2[i] = 10;
      if (EtaCutLevel_2 == 1)
        dEtaCut_2[i] = dEtaCut_Low[i];
      else if (EtaCutLevel_2 == 2)
        dEtaCut_2[i] = dEtaCut_Mid[i];
      else if (EtaCutLevel_2 == 3)
        dEtaCut_2[i] = dEtaCut_High_A[i];
      else if (EtaCutLevel_2 == 4)
        dEtaCut_2[i] = dEtaCut_High_B[i];
      else if (EtaCutLevel_2 == 5)
        dEtaCut_2[i] = dEtaCut_High_C[i];
      else if (EtaCutLevel_2 == 6)
        dEtaCut_2[i] = dEtaCut_Open[i];

      float scalef = 1.0;
      if (mode == 8 || mode == 10)
        dEtaCut_2[i] = scalef*dEtaCut_2[i];
      
    }
  
  

  eta = address.track_eta;
 
  fr = address.track_fr;
  charge = address.delta_phi_sign;
  quality = trackQuality(eta, mode, fr);
  unsigned front_pt, rear_pt;
  front_pt = 0.; rear_pt = 0.;
  unsigned front_quality, rear_quality;

  etaR = trigger_scale->getRegionalEtaScale(2)->getLowEdge(2*eta+1);

  front_quality = rear_quality = quality;

  unsigned int remerged;
  int iME11;
  int CLCT_pattern;
  int dEta;
  int index = 0;
  float bestLH = -999;
 float bestLH_front = -999.0;
 float bestLH_rear = -999.0;

 int PtbyMLH = false;
  
  //***************************************************//
  if(pt_method >= 29 && pt_method <= 33)
    {
        // using fw 2012_01_31. Switch to Global Log(L). Non-Linear dphi binning.
      PtbyMLH = 0x1 & (getPtbyMLH >> (int)mode);
      // switch off any improvment for eta > 2.1
      if(etaR > 2.1){
         usedetaCUT = false;
         PtbyMLH = 0x0;
      }
      
      switch(mode)
        {
        case 2:
        case 3:
        case 4:
        case 5:
  
      
      charge12 = 1;

      // First remake the 12-bit dPhi word from the core
      remerged = (address.delta_phi_12 | (address.delta_phi_23 << 8 ) );
      
      // Now separate it into 7-bit dPhi12 and 5-bit dPhi23 parts
      absPhi12 = ((1<<7)-1) &  remerged; 
      absPhi23 = ((1<<5)-1) & (remerged >> 7);

      // Now get the corresponding dPhi value in our phi-units using the inverse dPhi LUTs
      absPhi12 = dPhiNLBMap_7bit[absPhi12];
      absPhi23 = dPhiNLBMap_5bit[absPhi23];

      if(charge) charge23 = 1;
      else charge23 = -1;

      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      dphi23R = (static_cast<float>(absPhi23)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      if(charge12 * charge23 < 0) dphi23R = -dphi23R;

      ptR_front = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12R, dphi23R, PtbyMLH, bestLH, 1, int(pt_method));
      bestLH_front = bestLH;
      ptR_rear  = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12R, dphi23R, PtbyMLH, bestLH, 0, int(pt_method));    
      bestLH_rear = bestLH;
      
      if((pt_method == 29 || pt_method == 32 || pt_method == 30 || pt_method == 31) && mode != 5 && etaR > 2.1)//exclude mode without ME11a
        {
            float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
            float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
            float dphi23Rmin = dphi23R;
            float dphi23Rmax = dphi23R;
            //if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
            //if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
            float ptR_front_min = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12Rmin, dphi23Rmin, PtbyMLH, bestLH, 1, int(pt_method));
            float bestLH_front_min = bestLH;
            float ptR_rear_min = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12Rmin, dphi23Rmin,  PtbyMLH, bestLH, 0, int(pt_method));
            float bestLH_rear_min = bestLH;
            float ptR_front_max = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12Rmax, dphi23Rmax, PtbyMLH, bestLH, 1, int(pt_method));
            float bestLH_front_max = bestLH;
            float ptR_rear_max = ptMethods.Pt3Stn2012(int(mode), etaR, dphi12Rmax, dphi23Rmax,  PtbyMLH, bestLH, 0, int(pt_method));
            float bestLH_rear_max = bestLH;

            if (PtbyMLH)
              {
                float best_pt_front = ptR_front;
                float best_LH_front = bestLH_front;
                if (bestLH_front_min > best_LH_front)
                  {
                    best_pt_front = ptR_front_min;
                    best_LH_front = bestLH_front_min;
                  }
                if (bestLH_front_max > best_LH_front)
                  {
                    best_pt_front = ptR_front_max;
                    best_LH_front = bestLH_front_max;
                  }
                ptR_front = best_pt_front;

                float best_pt_rear = ptR_rear;
                float best_LH_rear = bestLH_rear;
                if (bestLH_rear_min > best_LH_rear)
                  {
                    best_pt_rear = ptR_rear_min;
                    best_LH_rear = bestLH_rear_min;
                  }
                if (bestLH_rear_max > best_LH_rear)
                  {
                    best_pt_rear = ptR_rear_max;
                    best_LH_rear = bestLH_rear_max;
                  }
                ptR_rear = best_pt_rear;
              }
            else
              {
                // select max pt solution for 3 links:
                ptR_front = std::max(ptR_front, ptR_front_min);
                ptR_front = std::max(ptR_front, ptR_front_max);
                ptR_rear = std::max(ptR_rear, ptR_rear_min);
                ptR_rear = std::max(ptR_rear, ptR_rear_max);
              }
        }
      break;
    case 6: // for mode 6, 7 and 13 add CLCT information in dph23 bit and iME11 in charge bit   
    case 7:
    case 13: // ME1-ME4
      
      // First remake the 12-bit dPhi word from the core
      remerged = (address.delta_phi_12 | (address.delta_phi_23 << 8 ) );
      // Now get 8-bit dPhi12 
      absPhi12 = ((1<<8)-1) & remerged; 
      // Now get 3-bit dEta
      dEta = ((1<<3)-1) & (remerged >> 8);
      // New get CLCT bit. CLCT = true if CLCTPattern = 8, 9, or 10, else 0.
      CLCT_pattern = 0x1 & (remerged >> 11);
      
      iME11 = int(charge); // = 0 if ME1/1, = 1 if ME1/2 or ME1/3 station 
      if(iME11 == 1 && etaR > 1.6) etaR = 1.55; // shift for ME1/2 station  
      if(iME11 == 0 && etaR < 1.6) etaR = 1.65; // shift for ME1/1 station

      // Get the 8-bit dPhi bin number  
      absPhi12 = ((1<<8)-1) & address.delta_phi_12;
      
      // Now get the corresponding dPhi value in our phi-units using the inverse dPhi LUTs
      absPhi12 = dPhiNLBMap_8bit[absPhi12];
      
      //int CLCT_pattern = static_cast<int>(address.delta_phi_23);
    
      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      
      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12R, PtbyMLH, bestLH, 1, int(pt_method));
      bestLH_front = bestLH;
      ptR_rear  = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12R, PtbyMLH, bestLH, 0, int(pt_method));
      bestLH_rear = bestLH;
      if((pt_method == 29 || pt_method == 32 || pt_method == 30 || pt_method == 31) && etaR > 2.1)//exclude tracks without ME11a 
        {
          float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
          float ptR_front_min = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12Rmin,  PtbyMLH, bestLH, 1, int(pt_method));
          float bestLH_front_min = bestLH;
          float ptR_rear_min = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12Rmin,   PtbyMLH, bestLH, 0, int(pt_method));
          float bestLH_rear_min = bestLH;

          if (PtbyMLH)
            {
              ptR_front = bestLH_front > bestLH_front_min ? ptR_front : ptR_front_min;
              ptR_rear  = bestLH_rear  > bestLH_rear_min ? ptR_rear : ptR_rear_min;
            }
          else
            {
              // select max pt solution for 3 links:
              ptR_front = std::max(ptR_front, ptR_front_min);
              ptR_rear = std::max(ptR_rear, ptR_rear_min);
            }
        }
      
      if( (!CLCT_pattern) && (ptR_front > 5.)) ptR_front = 5.;
      if( (!CLCT_pattern) && (ptR_rear > 5.)) ptR_rear = 5.;

       // Check dEta against reasonable values for high-pt muons
      index = 0;
      if (mode == 6) index = 0;
      if (mode == 7) index = 4;
      if (mode == 13) index = 8;
      
      if (usedetaCUT)
        {
          if (fabs(etaR)>1.2 && fabs(etaR)<=1.5)
            if (dEta>dEtaCut_1[index+0] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          if (fabs(etaR)>1.5 && fabs(etaR)<=1.65)
            if (dEta>dEtaCut_1[index+1])
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          
          if (fabs(etaR)>1.65 && fabs(etaR)<=2.1)
            if (dEta>dEtaCut_1[index+2] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          if (fabs(etaR)>2.1)
            if (dEta>dEtaCut_1[index+3] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
        }
            
      break;
    
    case 8:
    case 9:
    case 10:
      
      
      // First remake the 12-bit dPhi word from the core
      remerged = (address.delta_phi_12 | (address.delta_phi_23 << 8 ) );
      // Now get 9-bit dPhi12 
      absPhi12 = ((1<<9)-1) & remerged; 
      // Now get 3-bit dEta
      dEta = ((1<<3)-1) & (remerged >> 9);
     
      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12R,  PtbyMLH, bestLH, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt2Stn2012(int(mode), etaR, dphi12R,  PtbyMLH, bestLH, 0, int(pt_method));

      index = 0;
      if (mode == 8) index = 12;
      if (mode == 9) index = 16;
      if (mode == 10) index = 20;

      
      
      
      if (usedetaCUT)
        {
          if (fabs(etaR)>1.2 && fabs(etaR)<=1.5)
            if (dEta>dEtaCut_2[index+0] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          if (fabs(etaR)>1.5 && fabs(etaR)<=1.65)
            if (dEta>dEtaCut_2[index+1])
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          
          if (fabs(etaR)>1.65 && fabs(etaR)<=2.1)
            if (dEta>dEtaCut_2[index+2] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
          if (fabs(etaR)>2.1)
            if (dEta>dEtaCut_2[index+3] )
              {
                if (ptR_front > 5) ptR_front = 5;
                if (ptR_rear  > 5) ptR_rear  = 5;
              }
        }
            
      break;
    // for overlap DT-CSC region using curves from data 2010
    case 11: // FR = 1 -> b1-1-3,     FR = 0 -> b1-3 
    case 12: // FR = 1 -> b1-2-3,     FR = 0 -> b1-2 
    case 14: // FR = 1 -> b1-1-2-(3), FR = 0 -> b1-1
    
      
    //sign definition: sign dphi12 = Phi_DT - Phi_CSC
    //                 sing dphi23 = 5th sign. bit of phiBend
    // -> charge = 1 -> dphi12 = +, phiBend = -
    // -> charge = 0 -> dphi12 = +, phiBend = +    
        charge12 = 1;

        // DT tracks are still using linear dPhi binning
        absPhi12 = address.delta_phi_12;
        absPhi23 = address.delta_phi_23;

        if(charge) charge23 = -1;
        else charge23 = 1;

        dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
        dphi23R = float(absPhi23);
        if(charge12 * charge23 < 0) dphi23R = -dphi23R;

        int mode1;
        mode1 = int(mode);
        if(fr == 1 && mode1 == 11) mode1 = 14; // 3 station track we use dphi12 and phiBend for 2 and 3 station track

        ptR_front = ptMethods.Pt3Stn2012_DT(mode1, etaR, dphi12R, dphi23R,  PtbyMLH, bestLH, int(0), int(pt_method));
        ptR_rear = ptMethods.Pt3Stn2012_DT(mode1, etaR, dphi12R, dphi23R,   PtbyMLH, bestLH, int(0), int(pt_method));

      break;
    case 15: // halo trigger
    case 1: // tracks that fail delta phi cuts
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(3); // 2 GeV
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(3); 
      break;
    default: // Tracks in this category are not considered muons.
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(0); // 0 GeV 
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(0);
    };// end switch

  front_pt = trigger_ptscale->getPtScale()->getPacked(ptR_front);
  rear_pt  = trigger_ptscale->getPtScale()->getPacked(ptR_rear);

  } //end pt_methods 29


//***************************************************//
  if(pt_method >= 23 && pt_method <= 28){ //here we have only pt_methods greater then 
                       //for fw 20110118 <- 2011 data taking, curves from MC like method 4
  // mode definition you could find at page 6 & 7: 
  // http://www.phys.ufl.edu/~madorsky/sp/2011-11-18/sp_core_interface.pdf 
  // it is valid starting the beggining of 2011 
  //std::cout << " pt_method = " << pt_method << std::endl;//test 
  switch(mode)
    {
    case 2:
    case 3:
    case 4:
    case 5:

      charge12 = 1;
      absPhi12 = address.delta_phi_12;
      absPhi23 = address.delta_phi_23;

      if(charge) charge23 = 1;
      else charge23 = -1;

      dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      if(charge12 * charge23 < 0) dphi23R = -dphi23R;

      ptR_front = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12R, dphi23R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12R, dphi23R, 0, int(pt_method));    

      if((pt_method == 24 || pt_method == 26 || pt_method == 28) && mode != 5 && etaR > 2.1)//exclude mode without ME11a
        {
            float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
            float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
            float dphi23Rmin = dphi23R;
            float dphi23Rmax = dphi23R;
            //if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
            //if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
            float ptR_front_min = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12Rmin, dphi23Rmin, 1, int(pt_method));
            float ptR_rear_min = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12Rmin, dphi23Rmin, 0, int(pt_method));
            float ptR_front_max = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12Rmax, dphi23Rmax, 1, int(pt_method));
            float ptR_rear_max = ptMethods.Pt3Stn2010(int(mode), etaR, dphi12Rmax, dphi23Rmax, 0, int(pt_method));
            // select max pt solution for 3 links:
            ptR_front = std::max(ptR_front, ptR_front_min);
            ptR_front = std::max(ptR_front, ptR_front_max);
            ptR_rear = std::max(ptR_rear, ptR_rear_min);
            ptR_rear = std::max(ptR_rear, ptR_rear_max);
        }
      break;
    case 6: // for mode 6, 7 and 13 add CLCT information in dph23 bit and iME11 in charge bit  
    case 7:
    case 13: // ME1-ME4
      int iME11;
      iME11 = int(charge); // = 0 if ME1/1, = 1 if ME1/2 or ME1/3 station 
      if(iME11 == 1 && etaR > 1.6) etaR = 1.55; // shift for ME1/2 station  
      if(iME11 == 0 && etaR < 1.6) etaR = 1.65; // shift for ME1/1 station 
      absPhi12 = address.delta_phi_12;
      //int CLCT_pattern = static_cast<int>(address.delta_phi_23);
      int CLCT_pattern;
      CLCT_pattern = int(address.delta_phi_23);
      dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12R, 0, int(pt_method));
      if((pt_method == 24 || pt_method == 26 || pt_method == 28) && etaR > 2.1)//exclude tracks without ME11a 
        {
           float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
           float ptR_front_min = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12Rmin, 1, int(pt_method));
           float ptR_rear_min = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12Rmin, 0, int(pt_method));
           // select max pt solution for 3 links:
           ptR_front = std::max(ptR_front, ptR_front_min);
           ptR_rear = std::max(ptR_rear, ptR_rear_min);
        }
      if( ((CLCT_pattern < 8) || (CLCT_pattern > 10)) && (ptR_front > 5.)) ptR_front = 5.;
      if( ((CLCT_pattern < 8) || (CLCT_pattern > 10)) && (ptR_rear > 5.)) ptR_rear = 5.;
      //std::cout << "mode = "<< mode << " CLCT_pattern = " << CLCT_pattern << " ptR_rear = " << ptR_rear << std::endl;

      break;
    case 8:
    case 9:
    case 10:
      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }

      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt2Stn2010(int(mode), etaR, dphi12R, 0, int(pt_method));

      break;
    // for overlap DT-CSC region using curves from data 2010
    case 11: // FR = 1 -> b1-1-3,     FR = 0 -> b1-3 
    case 12: // FR = 1 -> b1-2-3,     FR = 0 -> b1-2 
    case 14: // FR = 1 -> b1-1-2-(3), FR = 0 -> b1-1

    //sign definition: sign dphi12 = Phi_DT - Phi_CSC
    //                 sing dphi23 = 5th sign. bit of phiBend
    // -> charge = 1 -> dphi12 = +, phiBend = -
    // -> charge = 0 -> dphi12 = +, phiBend = +    
        charge12 = 1;
        absPhi12 = address.delta_phi_12;
        absPhi23 = address.delta_phi_23;

        if(charge) charge23 = -1;
        else charge23 = 1;

        dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
        dphi23R = float(absPhi23);
        if(charge12 * charge23 < 0) dphi23R = -dphi23R;

        int mode1;
        mode1 = int(mode);
        if(fr == 1 && mode1 == 11) mode1 = 14; // 3 station track we use dphi12 and phiBend for 2 and 3 station track

        ptR_front = ptMethods.Pt3Stn2011(mode1, etaR, dphi12R, dphi23R, int(0), int(pt_method));
        ptR_rear = ptMethods.Pt3Stn2011(mode1, etaR, dphi12R, dphi23R, int(0), int(pt_method));

      break;
    case 15: // halo trigger
    case 1: // tracks that fail delta phi cuts
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(3); // 2 GeV
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(3); 
      break;
    default: // Tracks in this category are not considered muons.
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(0); // 0 GeV 
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(0);
    };// end switch

  front_pt = trigger_ptscale->getPtScale()->getPacked(ptR_front);
  rear_pt  = trigger_ptscale->getPtScale()->getPacked(ptR_rear);

  } //end pt_methods 23 - 28 

//***************************************************//
//***************************************************//
  if(pt_method == 21 || pt_method == 22){ //here we have only pt_methods greater then 
                       //for fw 20110118 <- 2011 data taking
  // mode definition you could find at page 6 & 7: 
  // http://www.phys.ufl.edu/~madorsky/sp/2011-11-18/sp_core_interface.pdf 
  // it is valid starting the beggining of 2011 
  switch(mode)
    {
    case 2:
    case 3:
    case 4:
    case 5:

      charge12 = 1;
      absPhi12 = address.delta_phi_12;
      absPhi23 = address.delta_phi_23;

      if(charge) charge23 = 1;
      else charge23 = -1;

      dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      if(charge12 * charge23 < 0) dphi23R = -dphi23R;

      ptR_front = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12R, dphi23R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12R, dphi23R, 0, int(pt_method));    

      if(pt_method == 22 && mode != 5 && etaR > 2.1)//exclude mode without ME11a
        {
            float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
            float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
            float dphi23Rmin = dphi23R;
            float dphi23Rmax = dphi23R;
            //if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
            //if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
            float ptR_front_min = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12Rmin, dphi23Rmin, 1, int(pt_method));
            float ptR_rear_min = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12Rmin, dphi23Rmin, 0, int(pt_method));
            float ptR_front_max = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12Rmax, dphi23Rmax, 1, int(pt_method));
            float ptR_rear_max = ptMethods.Pt3Stn2011(int(mode), etaR, dphi12Rmax, dphi23Rmax, 0, int(pt_method));
            // select max pt solution for 3 links:
            ptR_front = std::max(ptR_front, ptR_front_min);
            ptR_front = std::max(ptR_front, ptR_front_max);
            ptR_rear = std::max(ptR_rear, ptR_rear_min);
            ptR_rear = std::max(ptR_rear, ptR_rear_max);
        }
      break;
    case 6: // for mode 6, 7 and 13 add CLCT information in dph23 bit and iME11 in charge bit  
    case 7:
    case 13: // ME1-ME4
      int iME11;
      iME11 = int(charge);
      absPhi12 = address.delta_phi_12;
      //int CLCT_pattern = static_cast<int>(address.delta_phi_23);
      int CLCT_pattern;
      CLCT_pattern = int(address.delta_phi_23);

      dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12R, 1, int(pt_method), iME11);
      ptR_rear  = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12R, 0, int(pt_method), iME11);
      if((pt_method == 22) && etaR > 2.1)//exclude tracks without ME11a 
        {
           float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
           float ptR_front_min = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12Rmin, 1, int(pt_method), iME11);
           float ptR_rear_min = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12Rmin, 0, int(pt_method), iME11);
           // select max pt solution for 3 links:
           ptR_front = std::max(ptR_front, ptR_front_min);
           ptR_rear = std::max(ptR_rear, ptR_rear_min);
        }
      if( ((CLCT_pattern < 8) || (CLCT_pattern > 10)) && (ptR_front > 5.)) ptR_front = 5.;
      if( ((CLCT_pattern < 8) || (CLCT_pattern > 10)) && (ptR_rear > 5.)) ptR_rear = 5.;

      break;
    case 8:
    case 9:
    case 10:
      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }

      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12R, 1, int(pt_method), int(2));
      ptR_rear  = ptMethods.Pt2Stn2011(int(mode), etaR, dphi12R, 0, int(pt_method), int(2));

      break;
    case 11: // FR = 1 -> b1-1-3,     FR = 0 -> b1-3 
    case 12: // FR = 1 -> b1-2-3,     FR = 0 -> b1-2 
    case 14: // FR = 1 -> b1-1-2-(3), FR = 0 -> b1-1

    //sign definition: sign dphi12 = Phi_DT - Phi_CSC
    //                 sing dphi23 = 5th sign. bit of phiBend
    // -> charge = 1 -> dphi12 = +, phiBend = -
    // -> charge = 0 -> dphi12 = +, phiBend = +    
        charge12 = 1;
        absPhi12 = address.delta_phi_12;
        absPhi23 = address.delta_phi_23;

        if(charge) charge23 = -1;
        else charge23 = 1;

        dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
        dphi23R = float(absPhi23);
        if(charge12 * charge23 < 0) dphi23R = -dphi23R;

        int mode1;
        mode1 = int(mode);
        if(fr == 1 && mode1 == 11) mode1 = 14; // 3 station track we use dphi12 and phiBend for 2 and 3 station track

        ptR_front = ptMethods.Pt3Stn2011(mode1, etaR, dphi12R, dphi23R, int(0), int(pt_method));
        ptR_rear = ptMethods.Pt3Stn2011(mode1, etaR, dphi12R, dphi23R, int(0), int(pt_method));

      break;
    case 15: // halo trigger
    case 1: // tracks that fail delta phi cuts
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(3); // 2 GeV
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(3); 
      break;
    default: // Tracks in this category are not considered muons.
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(0); // 0 GeV 
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(0);
    };// end switch

  front_pt = trigger_ptscale->getPtScale()->getPacked(ptR_front);
  rear_pt  = trigger_ptscale->getPtScale()->getPacked(ptR_rear);

  } //end pt_methods greater or equal to 21 

//***************************************************//
//***************************************************//
  if(pt_method >= 11 && pt_method < 20){ //here we have only pt_methods greater or equal to 11 
                       //for fw 20101011 <- 2011 data taking
  // mode definition you could find at page 6 & 7: 
  // http://www.phys.ufl.edu/~madorsky/sp/2010-10-11/sp_core_interface.pdf 
  // it is valid starting the beggining of 2011 
  switch(mode)
    {
    case 2:
    case 3:
    case 4:
    case 5:

      charge12 = 1;
      absPhi12 = address.delta_phi_12;
      absPhi23 = address.delta_phi_23;

      if(charge) charge23 = 1;
      else charge23 = -1;

      dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
      if(charge12 * charge23 < 0) dphi23R = -dphi23R;

      ptR_front = ptMethods.Pt3Stn2010(mode, etaR, dphi12R, dphi23R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt3Stn2010(mode, etaR, dphi12R, dphi23R, 0, int(pt_method));    

      if(pt_method == 12 && mode != 5 && etaR > 2.1)//exclude mode without ME11a
        {
            float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
            float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
            float dphi23Rmin = dphi23R;
            float dphi23Rmax = dphi23R;
            if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
            if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
            float ptR_front_min = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmin, dphi23Rmin, 1, int(pt_method));
            float ptR_rear_min = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmin, dphi23Rmin, 0, int(pt_method));
            float ptR_front_max = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmax, dphi23Rmax, 1, int(pt_method));
            float ptR_rear_max = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmax, dphi23Rmax, 0, int(pt_method));
            // select max pt solution for 3 links:
            ptR_front = std::max(ptR_front, ptR_front_min);
            ptR_front = std::max(ptR_front, ptR_front_max);
            ptR_rear = std::max(ptR_rear, ptR_rear_min);
            ptR_rear = std::max(ptR_rear, ptR_rear_max);
        }
      break;
    case 6:
    case 7:
    case 8:
    case 9:
    case 10:
    case 13: // ME1-ME4
      type = mode - 5;

      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }

      dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

      //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
      ptR_front = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 1, int(pt_method));
      ptR_rear  = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 0, int(pt_method));
      if((pt_method == 12) && etaR > 2.1 && mode != 8 && mode !=9 && mode !=10)//exclude tracks without ME11a 
        {
           float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
           float ptR_front_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 1, int(pt_method));
           float ptR_rear_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 0, int(pt_method));
           // select max pt solution for 3 links:
           ptR_front = std::max(ptR_front, ptR_front_min);
           ptR_rear = std::max(ptR_rear, ptR_rear_min);
        }

      break;
    case 11: // FR = 1 -> b1-1-3,     FR = 0 -> b1-3 
    case 12: // FR = 1 -> b1-2-3,     FR = 0 -> b1-2 
    case 14: // FR = 1 -> b1-1-2-(3), FR = 0 -> b1-1

      if(fr == 0){ // 2 station track
        if(charge) absPhi12 = address.delta_phi();
        else
          {
            int temp_phi = address.delta_phi();
            absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
          }
          dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          ptR_rear  = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 0, int(pt_method));

      }// end fr == 0
      if(fr == 1){ // 3 station track
        charge12 = 1;
        absPhi12 = address.delta_phi_12;
        absPhi23 = address.delta_phi_23;

        if(charge) charge23 = 1;
        else charge23 = -1;

        dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
        dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
        if(charge12 * charge23 < 0) dphi23R = -dphi23R;

        ptR_front = ptMethods.Pt3Stn2010(mode, etaR, dphi12R, dphi23R, 1, int(pt_method));

        if(pt_method == 12 && mode != 5 && etaR > 2.1)//exclude mode without ME11a
          {
              float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
              float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
              float dphi23Rmin = dphi23R;
              float dphi23Rmax = dphi23R;
              if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
              if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
              float ptR_front_min = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmin, dphi23Rmin, 1, int(pt_method));
              float ptR_front_max = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmax, dphi23Rmax, 1, int(pt_method));
              // select max pt solution for 3 links:
              ptR_front = std::max(ptR_front, ptR_front_min);
              ptR_front = std::max(ptR_front, ptR_front_max);
          }
      } // end fr == 1 

      break;
    case 15: // halo trigger
    case 1: // tracks that fail delta phi cuts
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(3); // 2 GeV
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(3); 
      break;
    default: // Tracks in this category are not considered muons.
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(0); // 0 GeV 
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(0);
    };// end switch

  front_pt = trigger_ptscale->getPtScale()->getPacked(ptR_front);
  rear_pt  = trigger_ptscale->getPtScale()->getPacked(ptR_rear);

  } //end pt_methods greater or equal to 11 
//***************************************************//
  if(pt_method <= 5){ //here we have only pt_methods less or equal to 5
  // mode definition you could find at https://twiki.cern.ch/twiki/pub/Main/PtLUTs/mode_codes.xls
  // it is valid till the end 2010 

  //  kluge to use 2-stn track in overlap region
  //  see also where this routine is called, and encode LUTaddress, and assignPT
  if (pt_method != 4 && pt_method !=5 
      && (mode == 2 || mode == 3 || mode == 4) && (eta<3)) mode = 6;
  if (pt_method != 4 && pt_method !=5 && (mode == 5)
      && (eta<3)) mode = 8;

  switch(mode)
    {
    case 2:
    case 3:
    case 4:
    case 5:
      type = mode - 1;
      charge12 = 1;
      absPhi12 = address.delta_phi_12;
      absPhi23 = address.delta_phi_23;

      if(charge) charge23 = 1;
      else charge23 = -1;

      // now convert to real numbers for input into PT assignment algos.

      if(pt_method == 4 || pt_method == 5) // param method 2010
        {
          dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          if(charge12 * charge23 < 0) dphi23R = -dphi23R;

          ptR_front = ptMethods.Pt3Stn2010(mode, etaR, dphi12R, dphi23R, 1, int(pt_method));
          ptR_rear  = ptMethods.Pt3Stn2010(mode, etaR, dphi12R, dphi23R, 0, int(pt_method));

          if(pt_method == 5 && mode != 5 && etaR > 2.1)//exclude mode without ME11a
            {
                float dphi12Rmin = dphi12R - Pi*10/180/3; // 10/3 degrees 
                float dphi12Rmax = dphi12R + Pi*10/180/3; // 10/3 degrees
                float dphi23Rmin = dphi23R;
                float dphi23Rmax = dphi23R;
                if(dphi12Rmin*dphi12R < 0) dphi23Rmin = -dphi23R;
                if(dphi12Rmax*dphi12R < 0) dphi23Rmax = -dphi23R;
                float ptR_front_min = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmin, dphi23Rmin, 1, int(pt_method));
                float ptR_rear_min = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmin, dphi23Rmin, 0, int(pt_method));
                float ptR_front_max = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmax, dphi23Rmax, 1, int(pt_method));
                float ptR_rear_max = ptMethods.Pt3Stn2010(mode, etaR, dphi12Rmax, dphi23Rmax, 0, int(pt_method));
                // select max pt solution for 3 links:
                ptR_front = std::max(ptR_front, ptR_front_min);
                ptR_front = std::max(ptR_front, ptR_front_max);
                ptR_rear = std::max(ptR_rear, ptR_rear_min);
                ptR_rear = std::max(ptR_rear, ptR_rear_max);
            }
        }
      else if(pt_method == 1) // param method
        {
          dphi12R = (static_cast<float>(absPhi12<<1)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          dphi23R = (static_cast<float>(absPhi23<<4)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          if(charge12 * charge23 < 0) dphi23R = -dphi23R;

          ptR_front = ptMethods.Pt3Stn(type, etaR, dphi12R, dphi23R, 1);
          ptR_rear  = ptMethods.Pt3Stn(type, etaR, dphi12R, dphi23R, 0);

        }
      else if(pt_method == 2) // cathy's method
        {
          if(type <= 2)
            {
              ptR_front = ptMethods.Pt3StnChiSq(type+3, etaR, absPhi12<<1, ((charge == 0) ? -(absPhi23<<4) : (absPhi23<<4)), 1);
              ptR_rear  = ptMethods.Pt3StnChiSq(type+3, etaR, absPhi12<<1, ((charge == 0) ? -(absPhi23<<4) : (absPhi23<<4)), 0);
            }
          else
            {
              ptR_front = ptMethods.Pt2StnChiSq(type-2, etaR, absPhi12<<1, 1);
              ptR_rear  = ptMethods.Pt2StnChiSq(type-2, etaR, absPhi12<<1, 0);
            }

        }
      else // hybrid
        {

          if(type <= 2)
            {
              ptR_front = ptMethods.Pt3StnHybrid(type+3, etaR, absPhi12<<1, ((charge == 0) ? -(absPhi23<<4) : (absPhi23<<4)), 1);
              ptR_rear  = ptMethods.Pt3StnHybrid(type+3, etaR, absPhi12<<1, ((charge == 0) ? -(absPhi23<<4) : (absPhi23<<4)), 0);
            }
          else
            {
              ptR_front = ptMethods.Pt2StnHybrid(type-2, etaR, absPhi12<<1, 1);
              ptR_rear  = ptMethods.Pt2StnHybrid(type-2, etaR, absPhi12<<1, 0);
            }

        }
      break;
    case 6:
    case 7:
    case 8:
    case 9:
    case 10:
      type = mode - 5;

      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }

      if(absPhi12 < (1<<9))
        {
          if(pt_method == 1 || type == 5)
            {
              dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

              ptR_front = ptMethods.Pt2Stn(type, etaR, dphi12R, 1);
              ptR_rear  = ptMethods.Pt2Stn(type, etaR, dphi12R, 0);

            }
          else if(pt_method == 2)
            {
              ptR_front = ptMethods.Pt2StnChiSq(type-1, etaR, absPhi12, 1);
              ptR_rear  = ptMethods.Pt2StnChiSq(type-1, etaR, absPhi12, 0);
            }
          else
            {
              ptR_front = ptMethods.Pt2StnHybrid(type-1, etaR, absPhi12, 1);
              ptR_rear  = ptMethods.Pt2StnHybrid(type-1, etaR, absPhi12, 0);
            }
        }
      else
        {
          ptR_front = trigger_ptscale->getPtScale()->getLowEdge(1);
          ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(1);
        }
      if(pt_method == 4 || pt_method == 5) // param method 2010
        {
              dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

              //std::cout<< " Sector_rad = " << (CSCTFConstants::SECTOR_RAD) << std::endl;
              ptR_front = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 1, int(pt_method));
              ptR_rear  = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 0, int(pt_method));
              if((pt_method == 5) && etaR > 2.1 && mode != 8 && mode !=9 && mode !=10)//exclude tracks without ME11a 
                {
                   float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
                   float ptR_front_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 1, int(pt_method));
                   float ptR_rear_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 0, int(pt_method));
                   // select max pt solution for 3 links:
                   ptR_front = std::max(ptR_front, ptR_front_min);
                   ptR_rear = std::max(ptR_rear, ptR_rear_min);
                }
        }

      break;
    case 12:  // 1-2-b1 calculated only delta_phi12 = 2-b1
    case 14:
      type = 2;

      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }
      if(absPhi12 < (1<<9))
        {
          dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          ptR_front = ptMethods.Pt2Stn(type, etaR, dphi12R, 1);
          ptR_rear  = ptMethods.Pt2Stn(type, etaR, dphi12R, 0);
        }
      else
        {
          ptR_front = trigger_ptscale->getPtScale()->getLowEdge(1);
          ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(1);
        }
      if(pt_method == 4 || pt_method == 5) // param method 2010 
        {
              dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

              ptR_front = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 1, int(pt_method));
              ptR_rear  = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 0, int(pt_method));

              if(fabs(dphi12R)<0.01 && (ptR_rear < 10 || ptR_front < 10))
                std::cout << "dphi12R = " << dphi12R << " ptR_rear = " << ptR_rear
                << " ptR_front = " << ptR_front << " etaR = " << etaR << " mode = " << mode << std::endl;
        }
      break;
    case 13:
      type = 4;

      if(charge) absPhi12 = address.delta_phi();
      else
        {
          int temp_phi = address.delta_phi();
          absPhi12 = static_cast<unsigned>(-temp_phi) & 0xfff;
        }
      if(absPhi12 < (1<<9))
        {
          dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;
          ptR_front = ptMethods.Pt2Stn(type, etaR, dphi12R, 1);
          ptR_rear  = ptMethods.Pt2Stn(type, etaR, dphi12R, 0);
        }
      else
        {
          ptR_front = trigger_ptscale->getPtScale()->getLowEdge(1);
          ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(1);
        }

      if(pt_method == 4 || pt_method == 5) // param method 2010
        {
              dphi12R = (static_cast<float>(absPhi12)) / (static_cast<float>(1<<12)) * CSCTFConstants::SECTOR_RAD;

              ptR_front = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 1, int(pt_method));
              ptR_rear  = ptMethods.Pt2Stn2010(mode, etaR, dphi12R, 0, int(pt_method));
              if((pt_method == 5) && etaR > 2.1)//mode = 13: ME1-ME4 exclude tracks without ME11a 
                {
                   float dphi12Rmin = fabs(fabs(dphi12R) - Pi*10/180/3); // 10/3 degrees 
                   float ptR_front_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 1, int(pt_method));
                   float ptR_rear_min = ptMethods.Pt2Stn2010(mode, etaR, dphi12Rmin, 0, int(pt_method));
                   // select max pt solution for 3 links:
                   ptR_front = std::max(ptR_front, ptR_front_min);
                   ptR_rear = std::max(ptR_rear, ptR_rear_min);
                }
        }

      break;
    case 11:
      // singles trigger
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(5);
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(5);
      //ptR_front = trigger_ptscale->getPtScale()->getLowEdge(31);
      //ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(31);
      break;
    case 15:
      // halo trigger
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(5);
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(5);
      break;
    case 1:
      // tracks that fail delta phi cuts
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(5);
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(5); 
     break;
    default: // Tracks in this category are not considered muons.
      ptR_front = trigger_ptscale->getPtScale()->getLowEdge(0);
      ptR_rear  = trigger_ptscale->getPtScale()->getLowEdge(0);
    };

  front_pt = trigger_ptscale->getPtScale()->getPacked(ptR_front);
  rear_pt  = trigger_ptscale->getPtScale()->getPacked(ptR_rear);

  // kluge to set arbitrary Pt for some tracks with lousy resolution (and no param)
  if(pt_method != 4 && pt_method != 5) 
    {
      if ((front_pt==0 || front_pt==1) && (eta<3) && quality==1 && pt_method != 2) front_pt = 31;
      if ((rear_pt==0  || rear_pt==1) && (eta<3) && quality==1 && pt_method != 2) rear_pt = 31;
    }
  if(pt_method != 2 && pt_method != 4 && quality == 1)
    {
      if (front_pt < 5) front_pt = 5;
      if (rear_pt  < 5) rear_pt  = 5;
    }

  // in order to match the pt assignement of the previous routine
  if(isBeamStartConf && pt_method != 2 && pt_method != 4 && pt_method !=5) {
    if(quality == 3 && mode == 5) {
      
      if (front_pt < 5) front_pt = 5;
      if (rear_pt  < 5) rear_pt  = 5;
    }

    if(quality == 2 && mode > 7 && mode < 11) {
      
      if (front_pt < 5) front_pt = 5;
      if (rear_pt  < 5) rear_pt  = 5;
    }
  }

  } // end if for pt_method less or equal to 5
//***************************************************//

 
  result.front_rank = front_pt | front_quality << 5;
  result.rear_rank  = rear_pt  | rear_quality << 5;

  result.charge_valid_front = 1; //ptMethods.chargeValid(front_pt, quality, eta, pt_method);
  result.charge_valid_rear  = 1; //ptMethods.chargeValid(rear_pt, quality, eta, pt_method);


  /*  if (mode == 1) { 
    std::cout << "F_pt: "      << front_pt      << std::endl;
    std::cout << "R_pt: "      << rear_pt       << std::endl;
    std::cout << "F_quality: " << front_quality << std::endl;
    std::cout << "R_quality: " << rear_quality  << std::endl;
    std::cout << "F_rank: " << std::hex << result.front_rank << std::endl;
    std::cout << "R_rank: " << std::hex << result.rear_rank  << std::endl;
  }
  */
  return result;
}
CSCTFPtLUT& CSCTFPtLUT::operator= ( const CSCTFPtLUT )
ptdat CSCTFPtLUT::Pt ( const ptadd address) const

Definition at line 171 of file CSCTFPtLUT.cc.

References calcPt(), L1MuCSCPtLut::pt(), pt_lut, read_pt_lut_es, read_pt_lut_file, query::result, theL1MuCSCPtLut_, and tmp.

Referenced by Pt(), and CSCTFSectorProcessor::run().

{
  ptdat result;
  
  if(read_pt_lut_es) 
  {
    unsigned int shortAdd = (address.toint()& 0x1fffff);

    ptdat tmp( theL1MuCSCPtLut_->pt(shortAdd) );
  
    result = tmp;
  } 
  
  else if (read_pt_lut_file)
    {
      int shortAdd = (address.toint()& 0x1fffff);
      result = pt_lut[shortAdd];
    } 
  
  else
    result = calcPt(address);

  return result;
}
ptdat CSCTFPtLUT::Pt ( const unsigned &  delta_phi_12,
const unsigned &  delta_phi23,
const unsigned &  track_eta,
const unsigned &  track_mode,
const unsigned &  track_fr,
const unsigned &  delta_phi_sign 
) const

Definition at line 201 of file CSCTFPtLUT.cc.

References Pt().

{
  ptadd address;
  address.delta_phi_12 = delta_phi_12;
  address.delta_phi_23 = delta_phi_23;
  address.track_eta = track_eta;
  address.track_mode = track_mode;
  address.track_fr = track_fr;
  address.delta_phi_sign = delta_phi_sign;

  return Pt(address);
}
ptdat CSCTFPtLUT::Pt ( const unsigned &  delta_phi_12,
const unsigned &  track_eta,
const unsigned &  track_mode,
const unsigned &  track_fr,
const unsigned &  delta_phi_sign 
) const

Definition at line 216 of file CSCTFPtLUT.cc.

References Pt().

{
  ptadd address;
  address.delta_phi_12 = ((1<<8)-1)&delta_phi_12;
  address.delta_phi_23 = ((1<<4)-1)&(delta_phi_12>>8);
  address.track_eta = track_eta;
  address.track_mode = track_mode;
  address.track_fr = track_fr;
  address.delta_phi_sign = delta_phi_sign;

  return Pt(address);
}
ptdat CSCTFPtLUT::Pt ( const unsigned &  address) const

Definition at line 196 of file CSCTFPtLUT.cc.

References Pt().

{
  return Pt(ptadd(address));
}
void CSCTFPtLUT::readLUT ( ) [private]

Definition at line 1432 of file CSCTFPtLUT.cc.

References end, edm::FileInPath::fullPath(), i, isBinary, CSCBitWidths::kPtAddressWidth, pt_lut, pt_lut_file, and groupFilesInBlocks::temp.

Referenced by CSCTFPtLUT().

{
  std::ifstream PtLUT;

  if(isBinary)
    {
      PtLUT.open(pt_lut_file.fullPath().c_str(), std::ios::binary);
      PtLUT.seekg(0, std::ios::end);
      int length = PtLUT.tellg();;
      if( length == (1<<CSCBitWidths::kPtAddressWidth)*sizeof(short) )
        {
          PtLUT.seekg(0, std::ios::beg);
          PtLUT.read(reinterpret_cast<char*>(pt_lut),length);
        }
      else
        {
          edm::LogError("CSCPtLUT") << "File " << pt_lut_file.fullPath() << " is incorrect size!\n";
        }
      PtLUT.close();
    }
  else
    {
      PtLUT.open(pt_lut_file.fullPath().c_str());
      unsigned i = 0;
      unsigned short temp = 0;
      while(!PtLUT.eof() && i < 1 << CSCBitWidths::kPtAddressWidth)
        {
          PtLUT >> temp;
          pt_lut[i++] = (*reinterpret_cast<ptdat*>(&temp));
        }
      PtLUT.close();
    }
}
unsigned CSCTFPtLUT::trackQuality ( const unsigned &  eta,
const unsigned &  mode,
const unsigned &  fr 
) const [private]

DEA try increasing quality

Definition at line 1329 of file CSCTFPtLUT.cc.

References isBeamStartConf, lowQualityFlag, and pt_method.

Referenced by calcPt().

{
 // eta and mode should be only 4-bits, since that is the input to the large LUT
    if (eta>15 || mode>15)
      {
        //std::cout << "Error: Eta or Mode out of range in AU quality assignment" << std::endl;
        edm::LogError("CSCTFPtLUT::trackQuality()")<<"Eta or Mode out of range in AU quality assignment";
        return 0;
      }
    unsigned int quality;
    switch (mode) {
    case 2:
      quality = 3;
      if(pt_method > 10 && eta < 3) quality = 1; //eta < 1.2
      if(pt_method == 32 && eta >= 12) quality = 2; // eta > 2.1  
      break;
    case 3:
    case 4:
      //        quality = 2;
      quality = 3;
      if(pt_method == 32 && eta >= 12) quality = 2; // eta > 2.1  
      break;
    case 5:
      quality = 1;
      if (isBeamStartConf && eta >= 12 && pt_method < 20) // eta > 2.1
        quality = 3;
      if(pt_method == 27 || pt_method == 28 || pt_method == 29 || pt_method == 32 || pt_method == 30 || pt_method == 33) quality = 3;// all mode = 5 set to quality 3 due to a lot dead ME1/1a stations
      break;
    case 6:
      if (eta>=3) // eta > 1.2
        quality = 2;
      else
        quality = 1;
      if(pt_method == 32 && eta >= 12) quality = 1; // eta > 2.1  
      break;
    case 7:
      quality = 2;
      if(pt_method > 10 && eta < 3) quality = 1; //eta < 1.2  
      if(pt_method == 32 && eta >= 12) quality = 1; // eta > 2.1  
      break;
    case 8:
    case 9:
    case 10:
      quality = 1;
      if (isBeamStartConf && eta >= 12 && pt_method < 20) // eta > 2.1
        quality = 2;
      if((pt_method == 27 || pt_method == 28 || pt_method == 30) && (eta >= 7 && eta < 9)) quality = 2; //set to quality 2 for eta = 1.6-1.8 due to a lot dead ME1/1a stations
      break;
    case 11:
      // single LCTs
      quality = 1;
      // overlap region
      if(pt_method > 10 && fr == 0) quality = 2;
      if(pt_method > 10 && fr == 1) quality = 3;
      if(pt_method > 20 && fr == 0) quality = 3;
      break;
    case 12:
      quality = 3;
      // overlap region
      if(pt_method > 10 && fr == 0) quality = 2;
      if(pt_method > 10 && fr == 1) quality = 3;
      if(pt_method > 20 && fr == 0) quality = 3;
      break;
    case 13:
      quality = 2;
      if(pt_method == 32 && eta >= 12) quality = 1; // eta > 2.1  
      break;
    case 14:
      quality = 2;
      // overlap region
      if(pt_method > 10 && fr == 0) quality = 2;
      if(pt_method > 10 && fr == 1) quality = 3;
      if(pt_method > 20 && fr == 0) quality = 3;
      break;
    case 15:
      // halo triggers
      quality = 1;
      break;
      //DEA: keep muons that fail delta phi cut
    case 1:
      quality = 1;
      break;
    default:
      quality = 0;
      break;
    }

    // allow quality = 1 only in overlap region or eta = 1.6 region
    //    if ((quality == 1) && (eta >= 4) && (eta != 6) && (eta != 7)) quality = 0;
    //    if ( (quality == 1) && (eta >= 4) ) quality = 0;

    if ( (quality == 1) && (eta >= 4) && (eta < 11)
         && ((lowQualityFlag&4)==0) ) quality = 0;
    if ( (quality == 1) && (eta < 4) && ((lowQualityFlag&1)==0)
         && ((lowQualityFlag&4)==0) ) quality = 0;
    if ( (quality == 1) && (eta >=11) && ((lowQualityFlag&2)==0)
         && ((lowQualityFlag&4)==0) ) quality = 0;

    return quality;

}

Member Data Documentation

const int CSCTFPtLUT::dEtaCut_High_A = {3,3,4,7,3,2,4,7,5,5,5,7,2,2,2,2,3,3,3,3,2,2,2,2} [static]

Definition at line 51 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dEtaCut_High_B = {3,3,4,7,3,3,5,7,6,6,6,7,2,2,3,3,3,3,3,3,3,3,3,2} [static]

Definition at line 52 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dEtaCut_High_C = {4,4,5,7,4,3,6,7,7,7,7,7,3,3,3,3,4,4,4,4,3,3,3,3} [static]

Definition at line 53 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dEtaCut_Low = {2,2,2,7,2,1,2,7,3,3,3,7,1,1,1,1,2,2,2,2,1,1,1,1} [static]

Definition at line 49 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dEtaCut_Mid = {2,2,3,7,2,2,3,7,4,4,4,7,2,2,2,2,2,2,2,2,2,2,2,2} [static]

Definition at line 50 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dEtaCut_Open = {7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7} [static]

Definition at line 54 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dPhiNLBMap_5bit [static]
Initial value:
     {  0       ,       1       ,       2       ,       4       ,       5       ,       7       ,       9       ,       11      ,       13      ,       15      ,       18      ,       21      ,       24      ,       28      ,       32      ,       37      ,       41      ,       47      ,       53      ,       60      ,       67      ,       75      ,       84      ,       94      ,       105     ,       117     ,       131     ,       145     ,       162     ,       180     ,       200     ,       222}

Definition at line 44 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dPhiNLBMap_7bit [static]
Initial value:
  {     0       ,       1       ,       2       ,       3       ,       4       ,       5       ,       6       ,       8       ,       9       ,       10      ,       11      ,       12      ,       14      ,       15      ,       16      ,       17      ,       19      ,       20      ,       21      ,       23      ,       24      ,       26      ,       27      ,       29      ,       30      ,       32      ,       33      ,       35      ,       37      ,       38      ,       40      ,       42      ,       44      ,       45      ,       47      ,       49      ,       51      ,       53      ,       55      ,       57      ,       59      ,       61      ,       63      ,       65      ,       67      ,       70      ,       72      ,       74      ,       77      ,       79      ,       81      ,       84      ,       86      ,       89      ,       92      ,       94      ,       97      ,       100     ,       103     ,       105     ,       108     ,       111     ,       114     ,       117     ,       121     ,       124     ,       127     ,       130     ,       134     ,       137     ,       141     ,       144     ,       148     ,       151     ,       155     ,       159     ,       163     ,       167     ,       171     ,       175     ,       179     ,       183     ,       188     ,       192     ,       197     ,       201     ,       206     ,       210     ,       215     ,       220     ,       225     ,       230     ,       235     ,       241     ,       246     ,       251     ,       257     ,       263     ,       268     ,       274     ,       280     ,       286     ,       292     ,       299     ,       305     ,       312     ,       318     ,       325     ,       332     ,       339     ,       346     ,       353     ,       361     ,       368     ,       376     ,       383     ,       391     ,       399     ,       408     ,       416     ,       425     ,       433     ,       442     ,       451     ,       460     ,       469     ,       479     ,       489 }

Definition at line 45 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::dPhiNLBMap_8bit [static]
Initial value:
 {      0       ,       1       ,       2       ,       3       ,       4       ,       5       ,       6       ,       7       ,       8       ,       9       ,       10      ,       11      ,       12      ,       13      ,       14      ,       16      ,       17      ,       18      ,       19      ,       20      ,       21      ,       22      ,       23      ,       24      ,       25      ,       27      ,       28      ,       29      ,       30      ,       31      ,       32      ,       33      ,       35      ,       36      ,       37      ,       38      ,       39      ,       40      ,       42      ,       43      ,       44      ,       45      ,       46      ,       48      ,       49      ,       50      ,       51      ,       53      ,       54      ,       55      ,       56      ,       58      ,       59      ,       60      ,       61      ,       63      ,       64      ,       65      ,       67      ,       68      ,       69      ,       70      ,       72      ,       73      ,       74      ,       76      ,       77      ,       79      ,       80      ,       81      ,       83      ,       84      ,       85      ,       87      ,       88      ,       90      ,       91      ,       92      ,       94      ,       95      ,       97      ,       98      ,       100     ,       101     ,       103     ,       104     ,       105     ,       107     ,       108     ,       110     ,       111     ,       113     ,       115     ,       116     ,       118     ,       119     ,       121     ,       122     ,       124     ,       125     ,       127     ,       129     ,       130     ,       132     ,       133     ,       135     ,       137     ,       138     ,       140     ,       141     ,       143     ,       145     ,       146     ,       148     ,       150     ,       151     ,       153     ,       155     ,       157     ,       158     ,       160     ,       162     ,       163     ,       165     ,       167     ,       169     ,       171     ,       172     ,       174     ,       176     ,       178     ,       180     ,       181     ,       183     ,       185     ,       187     ,       189     ,       191     ,       192     ,       194     ,       196     ,       198     ,       200     ,       202     ,       204     ,       206     ,       208     ,       210     ,       212     ,       214     ,       216     ,       218     ,       220     ,       222     ,       224     ,       226     ,       228     ,       230     ,       232     ,       234     ,       236     ,       238     ,       240     ,       242     ,       244     ,       246     ,       249     ,       251     ,       253     ,       255     ,       257     ,       259     ,       261     ,       264     ,       266     ,       268     ,       270     ,       273     ,       275     ,       277     ,       279     ,       282     ,       284     ,       286     ,       289     ,       291     ,       293     ,       296     ,       298     ,       300     ,       303     ,       305     ,       307     ,       310     ,       312     ,       315     ,       317     ,       320     ,       322     ,       324     ,       327     ,       329     ,       332     ,       334     ,       337     ,       340     ,       342     ,       345     ,       347     ,       350     ,       352     ,       355     ,       358     ,       360     ,       363     ,       366     ,       368     ,       371     ,       374     ,       376     ,       379     ,       382     ,       385     ,       387     ,       390     ,       393     ,       396     ,       398     ,       401     ,       404     ,       407     ,       410     ,       413     ,       416     ,       419     ,       421     ,       424     ,       427     ,       430     ,       433     ,       436     ,       439     ,       442     ,       445     ,       448     ,       451     ,       454     ,       457     ,       461     ,       464     ,       467     ,       470     ,       473     ,       476     ,       479     ,       483     }

Definition at line 46 of file CSCTFPtLUT.h.

Referenced by calcPt().

const int CSCTFPtLUT::getPtbyMLH = 0xFFFF [static]

Definition at line 56 of file CSCTFPtLUT.h.

Referenced by calcPt().

Definition at line 73 of file CSCTFPtLUT.h.

Referenced by calcPt(), CSCTFPtLUT(), and trackQuality().

bool CSCTFPtLUT::isBinary [private]

Definition at line 73 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), and readLUT().

unsigned CSCTFPtLUT::lowQualityFlag [private]

Definition at line 75 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), and trackQuality().

Definition at line 71 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), Pt(), and readLUT().

Definition at line 74 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), and readLUT().

unsigned CSCTFPtLUT::pt_method [private]

Definition at line 75 of file CSCTFPtLUT.h.

Referenced by calcPt(), CSCTFPtLUT(), and trackQuality().

Definition at line 66 of file CSCTFPtLUT.h.

Referenced by calcPt(), and CSCTFPtLUT().

Definition at line 73 of file CSCTFPtLUT.h.

Referenced by Pt().

Definition at line 73 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), and Pt().

Definition at line 61 of file CSCTFPtLUT.h.

Referenced by CSCTFPtLUT(), and Pt().

Definition at line 63 of file CSCTFPtLUT.h.

Referenced by calcPt(), and CSCTFPtLUT().

Definition at line 62 of file CSCTFPtLUT.h.

Referenced by calcPt(), and CSCTFPtLUT().