KK. More...
#include <CSCTFPtLUT.h>
Public Member Functions | |
CSCTFPtLUT (const edm::EventSetup &c) | |
KK. | |
CSCTFPtLUT (const edm::ParameterSet &, const L1MuTriggerScales *scales, const L1MuTriggerPtScale *ptScale) | |
CSCTFPtLUT (const CSCTFPtLUT &) | |
CSCTFPtLUT & | operator= (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 |
ptdat * | pt_lut |
edm::FileInPath | pt_lut_file |
unsigned | pt_method |
CSCTFPtMethods | ptMethods |
bool | read_pt_lut_es |
bool | read_pt_lut_file |
const L1MuCSCPtLut * | theL1MuCSCPtLut_ |
const L1MuTriggerPtScale * | trigger_ptscale |
const L1MuTriggerScales * | trigger_scale |
KK.
Definition at line 16 of file CSCTFPtLUT.h.
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.
{}
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 & | ) |
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().
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().
ptdat CSCTFPtLUT::Pt | ( | const unsigned & | address | ) | const |
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; }
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] |
{ 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] |
{ 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] |
{ 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().
bool CSCTFPtLUT::isBeamStartConf [private] |
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().
ptdat* CSCTFPtLUT::pt_lut [private] |
Definition at line 71 of file CSCTFPtLUT.h.
Referenced by CSCTFPtLUT(), Pt(), and readLUT().
edm::FileInPath CSCTFPtLUT::pt_lut_file [private] |
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().
CSCTFPtMethods CSCTFPtLUT::ptMethods [private] |
Definition at line 66 of file CSCTFPtLUT.h.
Referenced by calcPt(), and CSCTFPtLUT().
bool CSCTFPtLUT::read_pt_lut_es [private] |
Definition at line 73 of file CSCTFPtLUT.h.
Referenced by Pt().
bool CSCTFPtLUT::read_pt_lut_file [private] |
Definition at line 73 of file CSCTFPtLUT.h.
Referenced by CSCTFPtLUT(), and Pt().
const L1MuCSCPtLut* CSCTFPtLUT::theL1MuCSCPtLut_ [private] |
Definition at line 61 of file CSCTFPtLUT.h.
Referenced by CSCTFPtLUT(), and Pt().
const L1MuTriggerPtScale* CSCTFPtLUT::trigger_ptscale [private] |
Definition at line 63 of file CSCTFPtLUT.h.
Referenced by calcPt(), and CSCTFPtLUT().
const L1MuTriggerScales* CSCTFPtLUT::trigger_scale [private] |
Definition at line 62 of file CSCTFPtLUT.h.
Referenced by calcPt(), and CSCTFPtLUT().