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MuonSeedCreator Class Reference

#include <MuonSeedCreator.h>

Public Types

typedef
MuonTransientTrackingRecHit::MuonRecHitContainer 
SegmentContainer
 

Public Member Functions

TrajectorySeed createSeed (int type, const SegmentContainer &seg, const std::vector< int > &layers, int NShower, int NShowerSeg)
 Create a seed from set of segments. More...
 
 MuonSeedCreator (const edm::ParameterSet &pset)
 Constructor. More...
 
void setBField (const MagneticField *theField)
 Cache Magnetic Field for current event. More...
 
 ~MuonSeedCreator ()
 Destructor. More...
 

Private Member Functions

void estimatePtCSC (const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
 Estimate transverse momentum of track from CSC measurements. More...
 
void estimatePtDT (const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
 Estimate transverse momentum of track from DT measurements. More...
 
void estimatePtOverlap (const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
 Estimate transverse momentum of track from CSC + DT measurements. More...
 
void estimatePtShowering (int &NShowers, int &NShowerSeg, double &pt, double &spt)
 Estimate transverse momentum of track from showering segment. More...
 
void estimatePtSingle (const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
 Estimate transverse momentum of track from single segment. More...
 
std::vector< double > getPt (const std::vector< double > &vParameters, double eta, double dPhi)
 Compute pt from parameters. More...
 
double scaledPhi (double dphi, double t1)
 Scale the dPhi from segment position. More...
 
void weightedPt (const std::vector< double > &ptEstimate, const std::vector< double > &sptEstimate, double &ptAvg, double &sptAvg)
 Compute weighted mean pt from different pt estimators. More...
 

Private Attributes

const MagneticFieldBField
 
std::vector< double > CSC01
 
std::vector< double > CSC01_1
 
std::vector< double > CSC02
 
std::vector< double > CSC03
 
std::vector< double > CSC12
 
std::vector< double > CSC12_1
 
std::vector< double > CSC12_2
 
std::vector< double > CSC12_3
 
std::vector< double > CSC13
 
std::vector< double > CSC13_2
 
std::vector< double > CSC13_3
 
std::vector< double > CSC14
 
std::vector< double > CSC14_3
 
std::vector< double > CSC23
 
std::vector< double > CSC23_1
 
std::vector< double > CSC23_2
 
std::vector< double > CSC24
 
std::vector< double > CSC24_1
 
std::vector< double > CSC34
 
std::vector< double > CSC34_1
 
bool debug
 
float defaultMomentum
 
std::vector< double > DT12
 
std::vector< double > DT12_1
 
std::vector< double > DT12_2
 
std::vector< double > DT13
 
std::vector< double > DT13_1
 
std::vector< double > DT13_2
 
std::vector< double > DT14
 
std::vector< double > DT14_1
 
std::vector< double > DT14_2
 
std::vector< double > DT23
 
std::vector< double > DT23_1
 
std::vector< double > DT23_2
 
std::vector< double > DT24
 
std::vector< double > DT24_1
 
std::vector< double > DT24_2
 
std::vector< double > DT34
 
std::vector< double > DT34_1
 
std::vector< double > DT34_2
 
std::vector< double > OL1213
 
std::vector< double > OL1222
 
std::vector< double > OL1232
 
std::vector< double > OL2213
 
std::vector< double > OL2222
 
std::vector< double > OL_1213
 
std::vector< double > OL_1222
 
std::vector< double > OL_1232
 
std::vector< double > OL_2213
 
std::vector< double > OL_2222
 
std::vector< double > SMB10
 
std::vector< double > SMB11
 
std::vector< double > SMB12
 
std::vector< double > SMB20
 
std::vector< double > SMB21
 
std::vector< double > SMB22
 
std::vector< double > SMB30
 
std::vector< double > SMB31
 
std::vector< double > SMB32
 
std::vector< double > SMB_10S
 
std::vector< double > SMB_11S
 
std::vector< double > SMB_12S
 
std::vector< double > SMB_20S
 
std::vector< double > SMB_21S
 
std::vector< double > SMB_22S
 
std::vector< double > SMB_30S
 
std::vector< double > SMB_31S
 
std::vector< double > SMB_32S
 
std::vector< double > SME11
 
std::vector< double > SME12
 
std::vector< double > SME13
 
std::vector< double > SME21
 
std::vector< double > SME22
 
std::vector< double > SME31
 
std::vector< double > SME32
 
std::vector< double > SME41
 
std::vector< double > SME_11S
 
std::vector< double > SME_12S
 
std::vector< double > SME_13S
 
std::vector< double > SME_21S
 
std::vector< double > SME_22S
 
double sysError
 
float theMaxMomentum
 
float theMinMomentum
 

Detailed Description

Creates seed from vector of segment

Determine pt of seed using various combination of segments from different layers (stations) Parameterization used to determine pt between layers i and j:

pt = [ c_0 + c_1 * (Delta phi_ij) + c_2 * (Delta phi_ij)^2 ] / eta

Author
Dominique Fortin - UCR

Definition at line 30 of file MuonSeedCreator.h.

Member Typedef Documentation

Definition at line 34 of file MuonSeedCreator.h.

Constructor & Destructor Documentation

MuonSeedCreator::MuonSeedCreator ( const edm::ParameterSet pset)
explicit

Constructor.

See header file for a description of this class.

Author
: Shih-Chuan Kao, Dominique Fortin - UCR

Definition at line 37 of file MuonSeedCreator.cc.

References CSC01_1, CSC02, CSC03, CSC12, CSC12_1, CSC12_2, CSC12_3, CSC13, CSC13_2, CSC13_3, CSC14, CSC14_3, CSC23, CSC23_1, CSC23_2, CSC24, CSC24_1, CSC34, CSC34_1, debug, defaultMomentum, DT12, DT12_1, DT12_2, DT13, DT13_1, DT13_2, DT14, DT14_1, DT14_2, DT23, DT23_1, DT23_2, DT24, DT24_1, DT24_2, DT34, DT34_1, DT34_2, edm::ParameterSet::getParameter(), OL1213, OL1222, OL1232, OL2222, OL_1213, OL_1222, OL_1232, OL_2213, OL_2222, SMB10, SMB11, SMB12, SMB20, SMB21, SMB22, SMB30, SMB31, SMB32, SMB_10S, SMB_11S, SMB_12S, SMB_20S, SMB_21S, SMB_22S, SMB_30S, SMB_31S, SMB_32S, SME11, SME12, SME13, SME21, SME22, SME31, SME32, SME41, SME_11S, SME_12S, SME_13S, SME_21S, SME_22S, sysError, theMaxMomentum, and theMinMomentum.

37  {
38 
39  theMinMomentum = pset.getParameter<double>("minimumSeedPt");
40  theMaxMomentum = pset.getParameter<double>("maximumSeedPt");
41  defaultMomentum = pset.getParameter<double>("defaultSeedPt");
42  debug = pset.getParameter<bool>("DebugMuonSeed");
43  sysError = pset.getParameter<double>("SeedPtSystematics");
44  // load seed PT parameters
45  DT12 = pset.getParameter<std::vector<double> >("DT_12");
46  DT13 = pset.getParameter<std::vector<double> >("DT_13");
47  DT14 = pset.getParameter<std::vector<double> >("DT_14");
48  DT23 = pset.getParameter<std::vector<double> >("DT_23");
49  DT24 = pset.getParameter<std::vector<double> >("DT_24");
50  DT34 = pset.getParameter<std::vector<double> >("DT_34");
51 
52  CSC01 = pset.getParameter<std::vector<double> >("CSC_01");
53  CSC12 = pset.getParameter<std::vector<double> >("CSC_12");
54  CSC02 = pset.getParameter<std::vector<double> >("CSC_02");
55  CSC13 = pset.getParameter<std::vector<double> >("CSC_13");
56  CSC03 = pset.getParameter<std::vector<double> >("CSC_03");
57  CSC14 = pset.getParameter<std::vector<double> >("CSC_14");
58  CSC23 = pset.getParameter<std::vector<double> >("CSC_23");
59  CSC24 = pset.getParameter<std::vector<double> >("CSC_24");
60  CSC34 = pset.getParameter<std::vector<double> >("CSC_34");
61 
62  OL1213 = pset.getParameter<std::vector<double> >("OL_1213");
63  OL1222 = pset.getParameter<std::vector<double> >("OL_1222");
64  OL1232 = pset.getParameter<std::vector<double> >("OL_1232");
65  OL1213 = pset.getParameter<std::vector<double> >("OL_1213");
66  OL2222 = pset.getParameter<std::vector<double> >("OL_1222");
67 
68  SME11 = pset.getParameter<std::vector<double> >("SME_11");
69  SME12 = pset.getParameter<std::vector<double> >("SME_12");
70  SME13 = pset.getParameter<std::vector<double> >("SME_13");
71  SME21 = pset.getParameter<std::vector<double> >("SME_21");
72  SME22 = pset.getParameter<std::vector<double> >("SME_22");
73  SME31 = pset.getParameter<std::vector<double> >("SME_31");
74  SME32 = pset.getParameter<std::vector<double> >("SME_32");
75  SME41 = pset.getParameter<std::vector<double> >("SME_41");
76 
77  SMB10 = pset.getParameter<std::vector<double> >("SMB_10");
78  SMB11 = pset.getParameter<std::vector<double> >("SMB_11");
79  SMB12 = pset.getParameter<std::vector<double> >("SMB_12");
80  SMB20 = pset.getParameter<std::vector<double> >("SMB_20");
81  SMB21 = pset.getParameter<std::vector<double> >("SMB_21");
82  SMB22 = pset.getParameter<std::vector<double> >("SMB_22");
83  SMB30 = pset.getParameter<std::vector<double> >("SMB_30");
84  SMB31 = pset.getParameter<std::vector<double> >("SMB_31");
85  SMB32 = pset.getParameter<std::vector<double> >("SMB_32");
86 
87  // Load dphi scale parameters
88  CSC01_1 = pset.getParameter<std::vector<double> >("CSC_01_1_scale");
89  CSC12_1 = pset.getParameter<std::vector<double> >("CSC_12_1_scale");
90  CSC12_2 = pset.getParameter<std::vector<double> >("CSC_12_2_scale");
91  CSC12_3 = pset.getParameter<std::vector<double> >("CSC_12_3_scale");
92  CSC13_2 = pset.getParameter<std::vector<double> >("CSC_13_2_scale");
93  CSC13_3 = pset.getParameter<std::vector<double> >("CSC_13_3_scale");
94  CSC14_3 = pset.getParameter<std::vector<double> >("CSC_14_3_scale");
95  CSC23_1 = pset.getParameter<std::vector<double> >("CSC_23_1_scale");
96  CSC23_2 = pset.getParameter<std::vector<double> >("CSC_23_2_scale");
97  CSC24_1 = pset.getParameter<std::vector<double> >("CSC_24_1_scale");
98  CSC34_1 = pset.getParameter<std::vector<double> >("CSC_34_1_scale");
99 
100  DT12_1 = pset.getParameter<std::vector<double> >("DT_12_1_scale");
101  DT12_2 = pset.getParameter<std::vector<double> >("DT_12_2_scale");
102  DT13_1 = pset.getParameter<std::vector<double> >("DT_13_1_scale");
103  DT13_2 = pset.getParameter<std::vector<double> >("DT_13_2_scale");
104  DT14_1 = pset.getParameter<std::vector<double> >("DT_14_1_scale");
105  DT14_2 = pset.getParameter<std::vector<double> >("DT_14_2_scale");
106  DT23_1 = pset.getParameter<std::vector<double> >("DT_23_1_scale");
107  DT23_2 = pset.getParameter<std::vector<double> >("DT_23_2_scale");
108  DT24_1 = pset.getParameter<std::vector<double> >("DT_24_1_scale");
109  DT24_2 = pset.getParameter<std::vector<double> >("DT_24_2_scale");
110  DT34_1 = pset.getParameter<std::vector<double> >("DT_34_1_scale");
111  DT34_2 = pset.getParameter<std::vector<double> >("DT_34_2_scale");
112 
113  OL_1213 = pset.getParameter<std::vector<double> >("OL_1213_0_scale");
114  OL_1222 = pset.getParameter<std::vector<double> >("OL_1222_0_scale");
115  OL_1232 = pset.getParameter<std::vector<double> >("OL_1232_0_scale");
116  OL_2213 = pset.getParameter<std::vector<double> >("OL_2213_0_scale");
117  OL_2222 = pset.getParameter<std::vector<double> >("OL_2222_0_scale");
118 
119  SMB_10S = pset.getParameter<std::vector<double> >("SMB_10_0_scale");
120  SMB_11S = pset.getParameter<std::vector<double> >("SMB_11_0_scale");
121  SMB_12S = pset.getParameter<std::vector<double> >("SMB_12_0_scale");
122  SMB_20S = pset.getParameter<std::vector<double> >("SMB_20_0_scale");
123  SMB_21S = pset.getParameter<std::vector<double> >("SMB_21_0_scale");
124  SMB_22S = pset.getParameter<std::vector<double> >("SMB_22_0_scale");
125  SMB_30S = pset.getParameter<std::vector<double> >("SMB_30_0_scale");
126  SMB_31S = pset.getParameter<std::vector<double> >("SMB_31_0_scale");
127  SMB_32S = pset.getParameter<std::vector<double> >("SMB_32_0_scale");
128 
129  SME_11S = pset.getParameter<std::vector<double> >("SME_11_0_scale");
130  SME_12S = pset.getParameter<std::vector<double> >("SME_12_0_scale");
131  SME_13S = pset.getParameter<std::vector<double> >("SME_13_0_scale");
132  SME_21S = pset.getParameter<std::vector<double> >("SME_21_0_scale");
133  SME_22S = pset.getParameter<std::vector<double> >("SME_22_0_scale");
134 
135 }
T getParameter(std::string const &) const
std::vector< double > DT13_2
std::vector< double > SMB32
std::vector< double > CSC23_1
std::vector< double > SMB_30S
std::vector< double > SMB_21S
std::vector< double > DT14_2
std::vector< double > DT23_2
std::vector< double > DT34_1
std::vector< double > DT14_1
std::vector< double > SME_22S
std::vector< double > SMB22
std::vector< double > OL1232
std::vector< double > DT34_2
std::vector< double > CSC24
std::vector< double > CSC23_2
std::vector< double > SMB20
std::vector< double > CSC14
std::vector< double > DT34
std::vector< double > CSC12_2
std::vector< double > CSC13_2
std::vector< double > CSC12_1
std::vector< double > SME12
std::vector< double > SME22
std::vector< double > SME21
std::vector< double > CSC13_3
std::vector< double > CSC34
std::vector< double > SME13
std::vector< double > DT13
std::vector< double > CSC12_3
std::vector< double > SMB10
std::vector< double > CSC12
std::vector< double > DT12_2
std::vector< double > OL_1222
std::vector< double > OL1222
std::vector< double > CSC23
std::vector< double > CSC13
std::vector< double > DT23_1
std::vector< double > SMB30
std::vector< double > SMB_10S
std::vector< double > DT24_2
std::vector< double > SMB_31S
std::vector< double > SMB_32S
std::vector< double > DT12_1
std::vector< double > CSC14_3
std::vector< double > DT12
std::vector< double > SMB_20S
std::vector< double > SMB_11S
std::vector< double > OL1213
std::vector< double > SMB12
std::vector< double > SME_21S
std::vector< double > SME_12S
std::vector< double > OL2222
std::vector< double > SME_11S
std::vector< double > DT14
std::vector< double > DT13_1
std::vector< double > SME31
std::vector< double > DT24
std::vector< double > OL_2213
std::vector< double > DT23
std::vector< double > SME32
std::vector< double > CSC24_1
std::vector< double > SMB21
std::vector< double > CSC01_1
std::vector< double > SME_13S
std::vector< double > OL_2222
std::vector< double > SMB31
std::vector< double > CSC03
std::vector< double > CSC02
std::vector< double > DT24_1
std::vector< double > CSC34_1
std::vector< double > SME11
std::vector< double > SMB11
std::vector< double > OL_1232
std::vector< double > SMB_12S
std::vector< double > SME41
Definition: QTest.h:566
std::vector< double > OL_1213
std::vector< double > SMB_22S
MuonSeedCreator::~MuonSeedCreator ( )

Destructor.

Definition at line 141 of file MuonSeedCreator.cc.

141  {
142 
143 }

Member Function Documentation

TrajectorySeed MuonSeedCreator::createSeed ( int  type,
const SegmentContainer seg,
const std::vector< int > &  layers,
int  NShower,
int  NShowerSeg 
)

Create a seed from set of segments.

get the Global position

get the Global direction

scale the magnitude of total momentum

Trasfer into local direction

get the Global position

get the Global direction

count the energy loss - from parameterization

scale the magnitude of total momentum

Trasfer into local direction

Definition at line 153 of file MuonSeedCreator.cc.

References alongMomentum, BField, RecoTauCleanerPlugins::charge, beam_dqm_sourceclient-live_cfg::chi2, clone(), gather_cfg::cout, debug, cuy::dh, relativeConstraints::error, estimatePtCSC(), estimatePtDT(), estimatePtOverlap(), estimatePtShowering(), estimatePtSingle(), eta, PV3DBase< T, PVType, FrameType >::eta(), i, cmsLHEtoEOSManager::l, plotBeamSpotDB::last, PV3DBase< T, PVType, FrameType >::perp(), trajectoryStateTransform::persistentState(), edm::OwnVector< T, P >::push_back(), lumiQTWidget::t, funct::tan(), theMaxMomentum, theMinMomentum, and PV3DBase< T, PVType, FrameType >::theta().

Referenced by MuonSeedBuilder::build().

153  {
154 
155  // The index of the station closest to the IP
156  int last = 0;
157 
158  double ptmean = theMinMomentum;
159  double sptmean = theMinMomentum;
160 
161  AlgebraicVector t(4);
162  AlgebraicSymMatrix mat(5,0) ;
163  LocalPoint segPos;
164 
165  // Compute the pt according to station types used;
166  if (type == 1 ) estimatePtCSC(seg, layers, ptmean, sptmean);
167  if (type == 2 ) estimatePtOverlap(seg, layers, ptmean, sptmean);
168  if (type == 3 ) estimatePtDT(seg, layers, ptmean, sptmean);
169  if (type == 4 ) estimatePtSingle(seg, layers, ptmean, sptmean);
170  // type 5 are the seeding for ME1/4
171  if (type == 5 ) estimatePtCSC(seg, layers, ptmean, sptmean);
172 
173  // for certain clear showering case, set-up the minimum value
174  if ( NShowers > 0 ) estimatePtShowering( NShowers, NShowerSegments, ptmean, sptmean );
175  //if ( NShowers > 0 ) std::cout<<" Showering happened "<<NShowers<<" times w/ "<< NShowerSegments<<std::endl; ;
176 
177 
178  // Minimal pt
179  double charge = 1.0;
180  if (ptmean < 0.) charge = -1.0;
181  if ( (charge * ptmean) < theMinMomentum ) {
182  ptmean = theMinMomentum * charge;
183  sptmean = theMinMomentum ;
184  }
185  else if ( (charge * ptmean) > theMaxMomentum ) {
186  ptmean = theMaxMomentum * charge;
187  sptmean = theMaxMomentum * 0.25 ;
188  }
189 
191 
192  double p_err =0.0;
193  // determine the seed layer
194  int best_seg= 0;
195  double chi2_dof = 9999.0;
196  unsigned int ini_seg = 0;
197  // avoid generating seed from 1st layer(ME1/1)
198  if ( type == 5 ) ini_seg = 1;
199  for (size_t i = ini_seg ; i < seg.size(); i++) {
200  double dof = static_cast<double>(seg[i]->degreesOfFreedom());
201  if ( chi2_dof < ( seg[i]->chi2()/dof ) ) continue;
202  chi2_dof = seg[i]->chi2() / dof ;
203  best_seg = static_cast<int>(i);
204  }
205 
206 
207  if ( type==1 || type==5 || type== 4) {
208  // Fill the LocalTrajectoryParameters
210  last = best_seg;
211  // last = 0;
212  GlobalVector mom = seg[last]->globalPosition()-GlobalPoint();
213  segPos = seg[last]->localPosition();
215 
216  GlobalVector polar(GlobalVector::Spherical(mom.theta(),seg[last]->globalDirection().phi(),1.));
217 
219  polar *= fabs(ptmean)/polar.perp();
221  LocalVector segDirFromPos = seg[last]->det()->toLocal(polar);
222  int chargeI = static_cast<int>(charge);
223  LocalTrajectoryParameters param1(segPos, segDirFromPos, chargeI);
224  param = param1;
225  p_err = (sptmean*sptmean)/(polar.mag()*polar.mag()*ptmean*ptmean) ;
226  mat = seg[last]->parametersError().similarityT( seg[last]->projectionMatrix() );
227  mat[0][0]= p_err;
228  if ( type == 5 ) {
229  mat[0][0] = mat[0][0]/fabs( tan(mom.theta()) );
230  mat[1][1] = mat[1][1]/fabs( tan(mom.theta()) );
231  mat[3][3] = 2.25*mat[3][3];
232  mat[4][4] = 2.25*mat[4][4];
233  }
234  if ( type == 4 ) {
235  mat[0][0] = mat[0][0]/fabs( tan(mom.theta()) );
236  mat[1][1] = mat[1][1]/fabs( tan(mom.theta()) );
237  mat[2][2] = 2.25*mat[2][2];
238  mat[3][3] = 2.25*mat[3][3];
239  mat[4][4] = 2.25*mat[4][4];
240  }
241  double dh = fabs( seg[last]->globalPosition().eta() ) - 1.6 ;
242  if ( fabs(dh) < 0.1 && type == 1 ) {
243  mat[1][1] = 4.*mat[1][1];
244  mat[2][2] = 4.*mat[2][2];
245  mat[3][3] = 9.*mat[3][3];
246  mat[4][4] = 9.*mat[4][4];
247  }
248 
249  //if ( !highPt && type != 1 ) mat[1][1]= 2.25*mat[1][1];
250  //if ( highPt && type != 1 ) mat[3][3]= 2.25*mat[1][1];
251  //mat[2][2]= 3.*mat[2][2];
252  //mat[3][3]= 2.*mat[3][3];
253  //mat[4][4]= 2.*mat[4][4];
254  }
255  else {
256  // Fill the LocalTrajectoryParameters
258  last = 0;
259  segPos = seg[last]->localPosition();
260  GlobalVector mom = seg[last]->globalPosition()-GlobalPoint();
262  GlobalVector polar(GlobalVector::Spherical(mom.theta(),seg[last]->globalDirection().phi(),1.));
263  //GlobalVector polar(GlobalVector::Spherical(seg[last]->globalDirection().theta(),seg[last]->globalDirection().phi(),1.));
264 
266  //double ptRatio = 1.0 - (2.808/(fabs(ptmean) -1)) + (4.546/( (fabs(ptmean)-1)*(fabs(ptmean)-1)) );
267  //ptmean = ptmean*ptRatio ;
268 
270  polar *= fabs(ptmean)/polar.perp();
272  LocalVector segDirFromPos = seg[last]->det()->toLocal(polar);
273  int chargeI = static_cast<int>(charge);
274  LocalTrajectoryParameters param1(segPos, segDirFromPos, chargeI);
275  param = param1;
276  p_err = (sptmean*sptmean)/(polar.mag()*polar.mag()*ptmean*ptmean) ;
277  mat = seg[last]->parametersError().similarityT( seg[last]->projectionMatrix() );
278  //mat[0][0]= 1.44 * p_err;
279  mat[0][0]= p_err;
280  }
281 
282  if ( debug ) {
283  GlobalPoint gp = seg[last]->globalPosition();
284  float Geta = gp.eta();
285 
286  std::cout << "Type " << type << " Nsegments " << layers.size() << " ";
287  std::cout << "pt " << ptmean << " errpt " << sptmean
288  << " eta " << Geta << " charge " << charge
289  << std::endl;
290  }
291 
292  // this perform H.T() * parErr * H, which is the projection of the
293  // the measurement error (rechit rf) to the state error (TSOS rf)
294  // Legend:
295  // H => is the 4x5 projection matrix
296  // parError the 4x4 parameter error matrix of the RecHit
297 
298 
299  LocalTrajectoryError error(asSMatrix<5>(mat));
300 
301  // Create the TrajectoryStateOnSurface
302  TrajectoryStateOnSurface tsos(param, error, seg[last]->det()->surface(),&*BField);
303 
304  // Take the DetLayer on which relies the segment
305  DetId id = seg[last]->geographicalId();
306 
307  // Transform it in a TrajectoryStateOnSurface
308 
309 
311 
313  for (unsigned l=0; l<seg.size(); l++) {
314  container.push_back( seg[l]->hit()->clone() );
315  //container.push_back(seg[l]->hit());
316  }
317 
318  TrajectorySeed theSeed(seedTSOS,container,alongMomentum);
319  return theSeed;
320 }
type
Definition: HCALResponse.h:21
int i
Definition: DBlmapReader.cc:9
std::vector< LayerSetAndLayers > layers(const SeedingLayerSetsHits &sets)
Definition: LayerTriplets.cc:4
T perp() const
Definition: PV3DBase.h:72
void estimatePtDT(const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
Estimate transverse momentum of track from DT measurements.
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
PTrajectoryStateOnDet persistentState(const TrajectoryStateOnSurface &ts, unsigned int detid)
void estimatePtOverlap(const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
Estimate transverse momentum of track from CSC + DT measurements.
const MagneticField * BField
void estimatePtSingle(const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
Estimate transverse momentum of track from single segment.
void estimatePtCSC(const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
Estimate transverse momentum of track from CSC measurements.
Geom::Theta< T > theta() const
Definition: PV3DBase.h:75
void push_back(D *&d)
Definition: OwnVector.h:290
void estimatePtShowering(int &NShowers, int &NShowerSeg, double &pt, double &spt)
Estimate transverse momentum of track from showering segment.
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Definition: DetId.h:18
CLHEP::HepVector AlgebraicVector
TEveGeoShape * clone(const TEveElement *element, TEveElement *parent)
Definition: eve_macros.cc:135
T eta() const
Definition: PV3DBase.h:76
CLHEP::HepSymMatrix AlgebraicSymMatrix
tuple cout
Definition: gather_cfg.py:145
tuple dh
Definition: cuy.py:353
void MuonSeedCreator::estimatePtCSC ( const SegmentContainer seg,
const std::vector< int > &  layers,
double &  pt,
double &  spt 
)
private

Estimate transverse momentum of track from CSC measurements.

Definition at line 332 of file MuonSeedCreator.cc.

References CSC02, CSC03, CSC12, CSC13, CSC13_2, CSC14, CSC14_3, CSC23, CSC23_1, CSC23_2, CSC24, CSC24_1, CSC34, CSC34_1, defaultMomentum, eta, getPt(), PV3DBase< T, PVType, FrameType >::phi(), EnergyCorrector::pt, scaledPhi(), jetcorrextractor::sign(), findQualityFiles::size, theMaxMomentum, and weightedPt().

Referenced by createSeed().

332  {
333 
334  unsigned size = seg.size();
335  if (size < 2) return;
336 
337  // reverse the segment and layer container first for pure CSC case
338  //if ( layers[0] > layers[ layers.size()-1 ] ) {
339  // reverse( layers.begin(), layers.end() );
340  // reverse( seg.begin(), seg.end() );
341  //}
342 
343  std::vector<double> ptEstimate;
344  std::vector<double> sptEstimate;
345 
346  thePt = defaultMomentum;
347  theSpt = defaultMomentum;
348 
349  double pt = 0.;
350  double spt = 0.;
351  GlobalPoint segPos[2];
352 
353  int layer0 = layers[0];
354  segPos[0] = seg[0]->globalPosition();
355  float eta = fabs( segPos[0].eta() );
356  //float corr = fabs( tan(segPos[0].theta()) );
357  // use pt from vertex information
358  /*
359  if ( layer0 == 0 ) {
360  SegmentContainer seg0;
361  seg0.push_back(seg[0]);
362  std::vector<int> lyr0(1,0);
363  estimatePtSingle( seg0, lyr0, thePt, theSpt);
364  ptEstimate.push_back( thePt );
365  sptEstimate.push_back( theSpt );
366  }
367  */
368 
369  //std::cout<<" estimate CSC "<<std::endl;
370 
371  unsigned idx1 = size;
372  if (size > 1) {
373  while ( idx1 > 1 ) {
374  idx1--;
375  int layer1 = layers[idx1];
376  if (layer0 == layer1) continue;
377  segPos[1] = seg[idx1]->globalPosition();
378 
379  double dphi = segPos[0].phi() - segPos[1].phi();
380  //double temp_dphi = dphi/corr;
381  double temp_dphi = dphi;
382 
383  double sign = 1.0;
384  if (temp_dphi < 0.) {
385  temp_dphi = -1.0*temp_dphi;
386  sign = -1.0;
387  }
388 
389  // Ensure that delta phi is not too small to prevent pt from blowing up
390  if (temp_dphi < 0.0001 ) {
391  temp_dphi = 0.0001 ;
392  pt = theMaxMomentum ;
393  spt = theMaxMomentum*0.25 ;
394  ptEstimate.push_back( pt*sign );
395  sptEstimate.push_back( spt );
396  }
397  // ME1 is inner-most
398  if ( layer0 == 0 && temp_dphi >= 0.0001 ) {
399 
400  // ME1/2 is outer-most
401  if ( layer1 == 1 ) {
402  //temp_dphi = scaledPhi(temp_dphi, CSC01_1[3] );
403  pt = getPt( CSC01, eta , temp_dphi )[0];
404  spt = getPt( CSC01, eta , temp_dphi )[1];
405  }
406  // ME2 is outer-most
407  else if ( layer1 == 2 ) {
408  //temp_dphi = scaledPhi(temp_dphi, CSC12_3[3] );
409  pt = getPt( CSC02, eta , temp_dphi )[0];
410  spt = getPt( CSC02, eta , temp_dphi )[1];
411  }
412  // ME3 is outer-most
413  else if ( layer1 == 3 ) {
414  //temp_dphi = scaledPhi(temp_dphi, CSC13_3[3] );
415  pt = getPt( CSC03, eta , temp_dphi )[0];
416  spt = getPt( CSC03, eta , temp_dphi )[1];
417  }
418  // ME4 is outer-most
419  else {
420  //temp_dphi = scaledPhi(temp_dphi, CSC14_3[3]);
421  pt = getPt( CSC14, eta , temp_dphi )[0];
422  spt = getPt( CSC14, eta , temp_dphi )[1];
423  }
424  ptEstimate.push_back( pt*sign );
425  sptEstimate.push_back( spt );
426  }
427 
428  // ME1/2,ME1/3 is inner-most
429  if ( layer0 == 1 ) {
430  // ME2 is outer-most
431  if ( layer1 == 2 ) {
432 
433  //if ( eta <= 1.2 ) { temp_dphi = scaledPhi(temp_dphi, CSC12_1[3]); }
434  //if ( eta > 1.2 ) { temp_dphi = scaledPhi(temp_dphi, CSC12_2[3]); }
435  pt = getPt( CSC12, eta , temp_dphi )[0];
436  spt = getPt( CSC12, eta , temp_dphi )[1];
437  }
438  // ME3 is outer-most
439  else if ( layer1 == 3 ) {
440  temp_dphi = scaledPhi(temp_dphi, CSC13_2[3]);
441  pt = getPt( CSC13, eta , temp_dphi )[0];
442  spt = getPt( CSC13, eta , temp_dphi )[1];
443  }
444  // ME4 is outer-most
445  else {
446  temp_dphi = scaledPhi(temp_dphi, CSC14_3[3]);
447  pt = getPt( CSC14, eta , temp_dphi )[0];
448  spt = getPt( CSC14, eta , temp_dphi )[1];
449  }
450  ptEstimate.push_back( pt*sign );
451  sptEstimate.push_back( spt );
452  }
453 
454  // ME2 is inner-most
455  if ( layer0 == 2 && temp_dphi > 0.0001 ) {
456 
457  // ME4 is outer-most
458  bool ME4av =false;
459  if ( layer1 == 4 ) {
460  temp_dphi = scaledPhi(temp_dphi, CSC24_1[3]);
461  pt = getPt( CSC24, eta , temp_dphi )[0];
462  spt = getPt( CSC24, eta , temp_dphi )[1];
463  ME4av = true;
464  }
465  // ME3 is outer-most
466  else {
467  // if ME2-4 is availabe , discard ME2-3
468  if ( !ME4av ) {
469  if ( eta <= 1.7 ) { temp_dphi = scaledPhi(temp_dphi, CSC23_1[3]); }
470  if ( eta > 1.7 ) { temp_dphi = scaledPhi(temp_dphi, CSC23_2[3]); }
471  pt = getPt( CSC23, eta , temp_dphi )[0];
472  spt = getPt( CSC23, eta , temp_dphi )[1];
473  }
474  }
475  ptEstimate.push_back( pt*sign );
476  sptEstimate.push_back( spt );
477  }
478 
479  // ME3 is inner-most
480  if ( layer0 == 3 && temp_dphi > 0.0001 ) {
481 
482  temp_dphi = scaledPhi(temp_dphi, CSC34_1[3]);
483  pt = getPt( CSC34, eta , temp_dphi )[0];
484  spt = getPt( CSC34, eta , temp_dphi )[1];
485  ptEstimate.push_back( pt*sign );
486  sptEstimate.push_back( spt );
487  }
488 
489  }
490  }
491 
492  // Compute weighted average if have more than one estimator
493  if ( ptEstimate.size() > 0 ) weightedPt( ptEstimate, sptEstimate, thePt, theSpt);
494 
495 }
std::vector< double > CSC23_1
std::vector< LayerSetAndLayers > layers(const SeedingLayerSetsHits &sets)
Definition: LayerTriplets.cc:4
std::vector< double > CSC24
void weightedPt(const std::vector< double > &ptEstimate, const std::vector< double > &sptEstimate, double &ptAvg, double &sptAvg)
Compute weighted mean pt from different pt estimators.
double sign(double x)
std::vector< double > CSC23_2
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
std::vector< double > CSC14
std::vector< double > CSC13_2
std::vector< double > CSC34
std::vector< double > CSC12
std::vector< double > CSC23
std::vector< double > CSC13
std::vector< double > CSC14_3
std::vector< double > getPt(const std::vector< double > &vParameters, double eta, double dPhi)
Compute pt from parameters.
std::vector< double > CSC24_1
double scaledPhi(double dphi, double t1)
Scale the dPhi from segment position.
std::vector< double > CSC03
std::vector< double > CSC02
std::vector< double > CSC34_1
tuple size
Write out results.
Definition: QTest.h:566
void MuonSeedCreator::estimatePtDT ( const SegmentContainer seg,
const std::vector< int > &  layers,
double &  pt,
double &  spt 
)
private

Estimate transverse momentum of track from DT measurements.

Definition at line 504 of file MuonSeedCreator.cc.

References defaultMomentum, DT12, DT12_1, DT12_2, DT13, DT13_1, DT13_2, DT14, DT14_1, DT14_2, DT23, DT23_1, DT23_2, DT24, DT24_1, DT24_2, DT34, DT34_1, DT34_2, eta, getPt(), PV3DBase< T, PVType, FrameType >::phi(), EnergyCorrector::pt, scaledPhi(), jetcorrextractor::sign(), findQualityFiles::size, theMaxMomentum, and weightedPt().

Referenced by createSeed(), and estimatePtOverlap().

504  {
505 
506  unsigned size = seg.size();
507  if (size < 2) return;
508 
509  std::vector<double> ptEstimate;
510  std::vector<double> sptEstimate;
511 
512  thePt = defaultMomentum;
513  theSpt = defaultMomentum;
514 
515  double pt = 0.;
516  double spt = 0.;
517  GlobalPoint segPos[2];
518 
519  int layer0 = layers[0];
520  segPos[0] = seg[0]->globalPosition();
521  float eta = fabs(segPos[0].eta());
522 
523  //std::cout<<" estimate DT "<<std::endl;
524  // inner-most layer
525  //for ( unsigned idx0 = 0; idx0 < size-1; ++idx0 ) {
526  // layer0 = layers[idx0];
527  // segPos[0] = seg[idx0]->globalPosition();
528  // outer-most layer
529  // for ( unsigned idx1 = idx0+1; idx1 < size; ++idx1 ) {
530  for ( unsigned idx1 = 1; idx1 <size ; ++idx1 ) {
531 
532  int layer1 = layers[idx1];
533  segPos[1] = seg[idx1]->globalPosition();
534 
535  //eta = fabs(segPos[1].eta());
536  //if (layer1 == -4) eta = fabs(segPos[0].eta());
537 
538  double dphi = segPos[0].phi() - segPos[1].phi();
539  double temp_dphi = dphi;
540 
541  // Ensure that delta phi is not too small to prevent pt from blowing up
542 
543  double sign = 1.0;
544  if (temp_dphi < 0.) {
545  temp_dphi = -temp_dphi;
546  sign = -1.0;
547  }
548 
549  if (temp_dphi < 0.0001 ) {
550  temp_dphi = 0.0001 ;
551  pt = theMaxMomentum ;
552  spt = theMaxMomentum*0.25 ;
553  ptEstimate.push_back( pt*sign );
554  sptEstimate.push_back( spt );
555  }
556 
557  // MB1 is inner-most
558  bool MB23av = false;
559  if (layer0 == -1 && temp_dphi > 0.0001 ) {
560  // MB2 is outer-most
561  if (layer1 == -2) {
562 
563  if ( eta <= 0.7 ) { temp_dphi = scaledPhi(temp_dphi, DT12_1[3]); }
564  if ( eta > 0.7 ) { temp_dphi = scaledPhi(temp_dphi, DT12_2[3]); }
565  pt = getPt( DT12, eta , temp_dphi )[0];
566  spt = getPt( DT12, eta , temp_dphi )[1];
567  MB23av = true;
568  }
569  // MB3 is outer-most
570  else if (layer1 == -3) {
571 
572  if ( eta <= 0.6 ) { temp_dphi = scaledPhi(temp_dphi, DT13_1[3]); }
573  if ( eta > 0.6 ) { temp_dphi = scaledPhi(temp_dphi, DT13_2[3]); }
574  pt = getPt( DT13, eta , temp_dphi )[0];
575  spt = getPt( DT13, eta , temp_dphi )[1];
576  MB23av = true;
577  }
578  // MB4 is outer-most
579  else {
580  if ( !MB23av ) {
581  if ( eta <= 0.52 ) { temp_dphi = scaledPhi(temp_dphi, DT14_1[3]); }
582  if ( eta > 0.52 ) { temp_dphi = scaledPhi(temp_dphi, DT14_2[3]); }
583  pt = getPt( DT14, eta , temp_dphi )[0];
584  spt = getPt( DT14, eta , temp_dphi )[1];
585  }
586  }
587  ptEstimate.push_back( pt*sign );
588  sptEstimate.push_back( spt );
589  }
590 
591  // MB2 is inner-most
592  if (layer0 == -2 && temp_dphi > 0.0001 ) {
593  // MB3 is outer-most
594  if ( layer1 == -3) {
595 
596  if ( eta <= 0.6 ) { temp_dphi = scaledPhi(temp_dphi, DT23_1[3]); }
597  if ( eta > 0.6 ) { temp_dphi = scaledPhi(temp_dphi, DT23_2[3]); }
598  pt = getPt( DT23, eta , temp_dphi )[0];
599  spt = getPt( DT23, eta , temp_dphi )[1];
600  }
601  // MB4 is outer-most
602  else {
603 
604  if ( eta <= 0.52 ) { temp_dphi = scaledPhi(temp_dphi, DT24_1[3]); }
605  if ( eta > 0.52 ) { temp_dphi = scaledPhi(temp_dphi, DT24_2[3]); }
606  pt = getPt( DT24, eta , temp_dphi )[0];
607  spt = getPt( DT24, eta , temp_dphi )[1];
608  }
609  ptEstimate.push_back( pt*sign );
610  sptEstimate.push_back( spt );
611  }
612 
613  // MB3 is inner-most -> only marginally useful to pick up the charge
614  if (layer0 == -3 && temp_dphi > 0.0001 ) {
615  // MB4 is outer-most
616 
617  if ( eta <= 0.51 ) { temp_dphi = scaledPhi(temp_dphi, DT34_1[3]); }
618  if ( eta > 0.51 ) { temp_dphi = scaledPhi(temp_dphi, DT34_2[3]); }
619  pt = getPt( DT34, eta , temp_dphi )[0];
620  spt = getPt( DT34, eta , temp_dphi )[1];
621  ptEstimate.push_back( pt*sign );
622  sptEstimate.push_back( spt );
623  }
624  }
625  //}
626 
627 
628  // Compute weighted average if have more than one estimator
629  if (ptEstimate.size() > 0 ) weightedPt( ptEstimate, sptEstimate, thePt, theSpt);
630 
631 }
std::vector< double > DT13_2
std::vector< double > DT14_2
std::vector< LayerSetAndLayers > layers(const SeedingLayerSetsHits &sets)
Definition: LayerTriplets.cc:4
std::vector< double > DT23_2
std::vector< double > DT34_1
std::vector< double > DT14_1
std::vector< double > DT34_2
void weightedPt(const std::vector< double > &ptEstimate, const std::vector< double > &sptEstimate, double &ptAvg, double &sptAvg)
Compute weighted mean pt from different pt estimators.
double sign(double x)
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
std::vector< double > DT34
std::vector< double > DT13
std::vector< double > DT12_2
std::vector< double > DT23_1
std::vector< double > DT24_2
std::vector< double > DT12_1
std::vector< double > DT12
std::vector< double > getPt(const std::vector< double > &vParameters, double eta, double dPhi)
Compute pt from parameters.
std::vector< double > DT14
std::vector< double > DT13_1
std::vector< double > DT24
std::vector< double > DT23
double scaledPhi(double dphi, double t1)
Scale the dPhi from segment position.
std::vector< double > DT24_1
tuple size
Write out results.
void MuonSeedCreator::estimatePtOverlap ( const SegmentContainer seg,
const std::vector< int > &  layers,
double &  pt,
double &  spt 
)
private

Estimate transverse momentum of track from CSC + DT measurements.

Definition at line 638 of file MuonSeedCreator.cc.

References defaultMomentum, estimatePtDT(), eta, getPt(), j, OL1213, OL1222, OL1232, OL2213, OL2222, OL_1213, OL_1222, OL_1232, OL_2213, OL_2222, PV3DBase< T, PVType, FrameType >::phi(), scaledPhi(), jetcorrextractor::sign(), findQualityFiles::size, theMaxMomentum, and weightedPt().

Referenced by createSeed().

638  {
639 
640  int size = layers.size();
641 
642  thePt = defaultMomentum;
643  theSpt = defaultMomentum;
644 
645  SegmentContainer segCSC;
646  std::vector<int> layersCSC;
647  SegmentContainer segDT;
648  std::vector<int> layersDT;
649 
650  // DT layers are numbered as -4 to -1, whereas CSC layers go from 0 to 4:
651  for ( unsigned j = 0; j < layers.size(); ++j ) {
652  if ( layers[j] > -1 ) {
653  segCSC.push_back(seg[j]);
654  layersCSC.push_back(layers[j]);
655  }
656  else {
657  segDT.push_back(seg[j]);
658  layersDT.push_back(layers[j]);
659  }
660  }
661 
662  std::vector<double> ptEstimate;
663  std::vector<double> sptEstimate;
664 
665  GlobalPoint segPos[2];
666  int layer0 = layers[0];
667  segPos[0] = seg[0]->globalPosition();
668  float eta = fabs(segPos[0].eta());
669  //std::cout<<" estimate OL "<<std::endl;
670 
671  if ( segDT.size() > 0 && segCSC.size() > 0 ) {
672  int layer1 = layers[size-1];
673  segPos[1] = seg[size-1]->globalPosition();
674 
675  double dphi = segPos[0].phi() - segPos[1].phi();
676  double temp_dphi = dphi;
677 
678  // Ensure that delta phi is not too small to prevent pt from blowing up
679 
680  double sign = 1.0;
681  if (temp_dphi < 0.) {
682  temp_dphi = -temp_dphi;
683  sign = -1.0;
684  }
685 
686  if (temp_dphi < 0.0001 ) {
687  temp_dphi = 0.0001 ;
688  thePt = theMaxMomentum ;
689  theSpt = theMaxMomentum*0.25 ;
690  ptEstimate.push_back( thePt*sign );
691  sptEstimate.push_back( theSpt );
692  }
693 
694  // MB1 is inner-most
695  if ( layer0 == -1 && temp_dphi > 0.0001 ) {
696  // ME1/3 is outer-most
697  if ( layer1 == 1 ) {
698  temp_dphi = scaledPhi(temp_dphi, OL_1213[3]);
699  thePt = getPt( OL1213, eta , temp_dphi )[0];
700  theSpt = getPt( OL1213, eta , temp_dphi )[1];
701  }
702  // ME2 is outer-most
703  else if ( layer1 == 2) {
704  temp_dphi = scaledPhi(temp_dphi, OL_1222[3]);
705  thePt = getPt( OL1222, eta , temp_dphi )[0];
706  theSpt = getPt( OL1222, eta , temp_dphi )[1];
707  }
708  // ME3 is outer-most
709  else {
710  temp_dphi = scaledPhi(temp_dphi, OL_1232[3]);
711  thePt = getPt( OL1232, eta , temp_dphi )[0];
712  theSpt = getPt( OL1232, eta , temp_dphi )[1];
713  }
714  ptEstimate.push_back(thePt*sign);
715  sptEstimate.push_back(theSpt);
716  }
717  // MB2 is inner-most
718  if ( layer0 == -2 && temp_dphi > 0.0001 ) {
719  // ME1/3 is outer-most
720  if ( layer1 == 1 ) {
721  temp_dphi = scaledPhi(temp_dphi, OL_2213[3]);
722  thePt = getPt( OL2213, eta , temp_dphi )[0];
723  theSpt = getPt( OL2213, eta , temp_dphi )[1];
724  ptEstimate.push_back(thePt*sign);
725  sptEstimate.push_back(theSpt);
726  }
727  // ME2 is outer-most
728  if ( layer1 == 2) {
729  temp_dphi = scaledPhi(temp_dphi, OL_2222[3]);
730  thePt = getPt( OL2222, eta , temp_dphi )[0];
731  theSpt = getPt( OL2222, eta , temp_dphi )[1];
732  }
733  }
734  }
735 
736  if ( segDT.size() > 1 ) {
737  estimatePtDT(segDT, layersDT, thePt, theSpt);
738  ptEstimate.push_back(thePt);
739  sptEstimate.push_back(theSpt);
740  }
741 
742  /*
743  // not useful ....and pt estimation is bad
744  if ( segCSC.size() > 1 ) {
745  // don't estimate pt without ME1 information
746  bool CSCLayer1=false;
747  for (unsigned i=0; i< layersCSC.size(); i++) {
748  if ( layersCSC[i]==0 || layersCSC[i]==1 ) CSCLayer1 = true;
749  }
750  if (CSCLayer1) {
751  estimatePtCSC(segCSC, layersCSC, thePt, theSpt);
752  ptEstimate.push_back(thePt);
753  sptEstimate.push_back(theSpt);
754  }
755  }
756  */
757 
758  // Compute weighted average if have more than one estimator
759  if (ptEstimate.size() > 0 ) weightedPt( ptEstimate, sptEstimate, thePt, theSpt);
760 
761 }
std::vector< double > OL2213
std::vector< LayerSetAndLayers > layers(const SeedingLayerSetsHits &sets)
Definition: LayerTriplets.cc:4
std::vector< double > OL1232
void estimatePtDT(const SegmentContainer &seg, const std::vector< int > &layers, double &pt, double &spt)
Estimate transverse momentum of track from DT measurements.
void weightedPt(const std::vector< double > &ptEstimate, const std::vector< double > &sptEstimate, double &ptAvg, double &sptAvg)
Compute weighted mean pt from different pt estimators.
double sign(double x)
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
MuonTransientTrackingRecHit::MuonRecHitContainer SegmentContainer
std::vector< double > OL_1222
std::vector< double > OL1222
int j
Definition: DBlmapReader.cc:9
std::vector< double > OL1213
std::vector< double > getPt(const std::vector< double > &vParameters, double eta, double dPhi)
Compute pt from parameters.
std::vector< double > OL2222
std::vector< double > OL_2213
double scaledPhi(double dphi, double t1)
Scale the dPhi from segment position.
std::vector< double > OL_2222
std::vector< double > OL_1232
tuple size
Write out results.
std::vector< double > OL_1213
void MuonSeedCreator::estimatePtShowering ( int &  NShowers,
int &  NShowerSeg,
double &  pt,
double &  spt 
)
private

Estimate transverse momentum of track from showering segment.

Definition at line 901 of file MuonSeedCreator.cc.

Referenced by createSeed().

901  {
902 
903  if ( NShowers > 2 && thePt < 300. ) {
904  thePt = 800. ;
905  theSpt = 200. ;
906  }
907  if ( NShowers == 2 && NShowerSegments > 11 && thePt < 150. ) {
908  thePt = 280. ;
909  theSpt = 70. ;
910  }
911  if ( NShowers == 2 && NShowerSegments <= 11 && thePt < 50. ) {
912  thePt = 80.;
913  theSpt = 40. ;
914  }
915  if ( NShowers == 1 && NShowerSegments <= 5 && thePt < 10. ) {
916  thePt = 16. ;
917  theSpt = 8. ;
918  }
919 
920 }
void MuonSeedCreator::estimatePtSingle ( const SegmentContainer seg,
const std::vector< int > &  layers,
double &  pt,
double &  spt 
)
private

Estimate transverse momentum of track from single segment.

Definition at line 767 of file MuonSeedCreator.cc.

References defaultMomentum, eta, PV3DBase< T, PVType, FrameType >::eta(), getPt(), scaledPhi(), jetcorrextractor::sign(), SMB10, SMB11, SMB12, SMB20, SMB21, SMB22, SMB30, SMB31, SMB32, SMB_10S, SMB_11S, SMB_12S, SMB_20S, SMB_21S, SMB_22S, SMB_30S, SMB_31S, SMB_32S, SME11, SME12, SME13, SME21, SME22, SME_12S, SME_13S, SME_21S, SME_22S, mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by createSeed().

767  {
768 
769  thePt = defaultMomentum;
770  theSpt = defaultMomentum;
771 
772  GlobalPoint segPos = seg[0]->globalPosition();
773  double eta = segPos.eta();
774  GlobalVector gv = seg[0]->globalDirection();
775 
776  // Psi is angle between the segment origin and segment direction
777  // Use dot product between two vectors to get Psi in global x-y plane
778  double cosDpsi = (gv.x()*segPos.x() + gv.y()*segPos.y());
779  cosDpsi /= sqrt(segPos.x()*segPos.x() + segPos.y()*segPos.y());
780  cosDpsi /= sqrt(gv.x()*gv.x() + gv.y()*gv.y());
781 
782  double axb = ( segPos.x()*gv.y() ) - ( segPos.y()*gv.x() ) ;
783  double sign = (axb < 0.) ? 1.0 : -1.0;
784 
785  double dpsi = fabs(acos(cosDpsi)) ;
786  if ( dpsi > 1.570796 ) {
787  dpsi = 3.141592 - dpsi;
788  sign = -1.*sign ;
789  }
790  if (fabs(dpsi) < 0.00005) {
791  dpsi = 0.00005;
792  }
793 
794  // the 1st layer
795  if ( layers[0] == -1 ) {
796  // MB10
797  if ( fabs(eta) < 0.3 ) {
798  dpsi = scaledPhi(dpsi, SMB_10S[3] );
799  thePt = getPt( SMB10, eta , dpsi )[0];
800  theSpt = getPt( SMB10, eta , dpsi )[1];
801  }
802  // MB11
803  if ( fabs(eta) >= 0.3 && fabs(eta) < 0.82 ) {
804  dpsi = scaledPhi(dpsi, SMB_11S[3] );
805  thePt = getPt( SMB11, eta , dpsi )[0];
806  theSpt = getPt( SMB11, eta , dpsi )[1];
807  }
808  // MB12
809  if ( fabs(eta) >= 0.82 && fabs(eta) < 1.2 ) {
810  dpsi = scaledPhi(dpsi, SMB_12S[3] );
811  thePt = getPt( SMB12, eta , dpsi )[0];
812  theSpt = getPt( SMB12, eta , dpsi )[1];
813  }
814  }
815  if ( layers[0] == 1 ) {
816  // ME13
817  if ( fabs(eta) > 0.92 && fabs(eta) < 1.16 ) {
818  dpsi = scaledPhi(dpsi, SME_13S[3] );
819  thePt = getPt( SME13, eta , dpsi )[0];
820  theSpt = getPt( SME13, eta , dpsi )[1];
821  }
822  // ME12
823  if ( fabs(eta) >= 1.16 && fabs(eta) <= 1.6 ) {
824  dpsi = scaledPhi(dpsi, SME_12S[3] );
825  thePt = getPt( SME12, eta , dpsi )[0];
826  theSpt = getPt( SME12, eta , dpsi )[1];
827  }
828  }
829  if ( layers[0] == 0 ) {
830  // ME11
831  if ( fabs(eta) > 1.6 ) {
832  dpsi = scaledPhi(dpsi, SMB_11S[3] );
833  thePt = getPt( SME11, eta , dpsi )[0];
834  theSpt = getPt( SME11, eta , dpsi )[1];
835  }
836  }
837  // the 2nd layer
838  if ( layers[0] == -2 ) {
839  // MB20
840  if ( fabs(eta) < 0.25 ) {
841  dpsi = scaledPhi(dpsi, SMB_20S[3] );
842  thePt = getPt( SMB20, eta , dpsi )[0];
843  theSpt = getPt( SMB20, eta , dpsi )[1];
844  }
845  // MB21
846  if ( fabs(eta) >= 0.25 && fabs(eta) < 0.72 ) {
847  dpsi = scaledPhi(dpsi, SMB_21S[3] );
848  thePt = getPt( SMB21, eta , dpsi )[0];
849  theSpt = getPt( SMB21, eta , dpsi )[1];
850  }
851  // MB22
852  if ( fabs(eta) >= 0.72 && fabs(eta) < 1.04 ) {
853  dpsi = scaledPhi(dpsi, SMB_22S[3] );
854  thePt = getPt( SMB22, eta , dpsi )[0];
855  theSpt = getPt( SMB22, eta , dpsi )[1];
856  }
857  }
858  if ( layers[0] == 2 ) {
859  // ME22
860  if ( fabs(eta) > 0.95 && fabs(eta) <= 1.6 ) {
861  dpsi = scaledPhi(dpsi, SME_22S[3] );
862  thePt = getPt( SME22, eta , dpsi )[0];
863  theSpt = getPt( SME22, eta , dpsi )[1];
864  }
865  // ME21
866  if ( fabs(eta) > 1.6 && fabs(eta) < 2.45 ) {
867  dpsi = scaledPhi(dpsi, SME_21S[3] );
868  thePt = getPt( SME21, eta , dpsi )[0];
869  theSpt = getPt( SME21, eta , dpsi )[1];
870  }
871  }
872 
873  // the 3rd layer
874  if ( layers[0] == -3 ) {
875  // MB30
876  if ( fabs(eta) <= 0.22 ) {
877  dpsi = scaledPhi(dpsi, SMB_30S[3] );
878  thePt = getPt( SMB30, eta , dpsi )[0];
879  theSpt = getPt( SMB30, eta , dpsi )[1];
880  }
881  // MB31
882  if ( fabs(eta) > 0.22 && fabs(eta) <= 0.6 ) {
883  dpsi = scaledPhi(dpsi, SMB_31S[3] );
884  thePt = getPt( SMB31, eta , dpsi )[0];
885  theSpt = getPt( SMB31, eta , dpsi )[1];
886  }
887  // MB32
888  if ( fabs(eta) > 0.6 && fabs(eta) < 0.95 ) {
889  dpsi = scaledPhi(dpsi, SMB_32S[3] );
890  thePt = getPt( SMB32, eta , dpsi )[0];
891  theSpt = getPt( SMB32, eta , dpsi )[1];
892  }
893  }
894  thePt = fabs(thePt)*sign;
895  theSpt = fabs(theSpt);
896 
897  return;
898 }
std::vector< double > SMB32
std::vector< double > SMB_30S
std::vector< double > SMB_21S
std::vector< LayerSetAndLayers > layers(const SeedingLayerSetsHits &sets)
Definition: LayerTriplets.cc:4
std::vector< double > SME_22S
std::vector< double > SMB22
double sign(double x)
std::vector< double > SMB20
T y() const
Definition: PV3DBase.h:63
std::vector< double > SME12
std::vector< double > SME22
std::vector< double > SME21
std::vector< double > SME13
std::vector< double > SMB10
T sqrt(T t)
Definition: SSEVec.h:18
std::vector< double > SMB30
std::vector< double > SMB_10S
std::vector< double > SMB_31S
std::vector< double > SMB_32S
std::vector< double > SMB_20S
std::vector< double > SMB_11S
std::vector< double > getPt(const std::vector< double > &vParameters, double eta, double dPhi)
Compute pt from parameters.
std::vector< double > SMB12
std::vector< double > SME_21S
std::vector< double > SME_12S
T eta() const
Definition: PV3DBase.h:76
std::vector< double > SMB21
double scaledPhi(double dphi, double t1)
Scale the dPhi from segment position.
std::vector< double > SME_13S
std::vector< double > SMB31
std::vector< double > SME11
T x() const
Definition: PV3DBase.h:62
std::vector< double > SMB11
std::vector< double > SMB_12S
std::vector< double > SMB_22S
std::vector< double > MuonSeedCreator::getPt ( const std::vector< double > &  vParameters,
double  eta,
double  dPhi 
)
private

Compute pt from parameters.

Definition at line 992 of file MuonSeedCreator.cc.

References h.

Referenced by estimatePtCSC(), estimatePtDT(), estimatePtOverlap(), and estimatePtSingle().

992  {
993 
994  double h = fabs(eta);
995  double estPt = ( vPara[0] + vPara[1]*h + vPara[2]*h*h ) / dPhi;
996  double estSPt = ( vPara[3] + vPara[4]*h + vPara[5]*h*h ) * estPt;
997  std::vector<double> paraPt ;
998  paraPt.push_back( estPt );
999  paraPt.push_back( estSPt ) ;
1000 
1001  //std::cout<<" pt:"<<estPt<<" +/-"<< estSPt<<" h:"<<eta<<" df:"<<dPhi<<std::endl;
1002  return paraPt ;
1003 }
FWCore Framework interface EventSetupRecordImplementation h
Helper function to determine trigger accepts.
double dPhi(double phi1, double phi2)
Definition: JetUtil.h:30
double MuonSeedCreator::scaledPhi ( double  dphi,
double  t1 
)
private

Scale the dPhi from segment position.

Definition at line 1005 of file MuonSeedCreator.cc.

Referenced by estimatePtCSC(), estimatePtDT(), estimatePtOverlap(), and estimatePtSingle().

1005  {
1006 
1007  if (dphi != 0. ) {
1008 
1009  double oPhi = 1./dphi ;
1010  dphi = dphi /( 1. + t1/( oPhi + 10. ) ) ;
1011  return dphi ;
1012 
1013  } else {
1014  return dphi ;
1015  }
1016 
1017 }
void MuonSeedCreator::setBField ( const MagneticField theField)
inline

Cache Magnetic Field for current event.

Definition at line 45 of file MuonSeedCreator.h.

References BField.

Referenced by MuonSeedBuilder::build().

45 { BField = theField; };
const MagneticField * BField
void MuonSeedCreator::weightedPt ( const std::vector< double > &  ptEstimate,
const std::vector< double > &  sptEstimate,
double &  ptAvg,
double &  sptAvg 
)
private

Compute weighted mean pt from different pt estimators.

Definition at line 928 of file MuonSeedCreator.cc.

References RecoTauCleanerPlugins::charge, j, findQualityFiles::size, and mathSSE::sqrt().

Referenced by estimatePtCSC(), estimatePtDT(), and estimatePtOverlap().

928  {
929 
930 
931  int size = ptEstimate.size();
932 
933  // If only one element, by-pass computation below
934  if (size < 2) {
935  thePt = ptEstimate[0];
936  theSpt = sptEstimate[0];
937  return;
938  }
939 
940  double charge = 0.;
941  // If have more than one pt estimator, first look if any estimator is biased
942  // by comparing the charge of each estimator
943 
944  for ( unsigned j = 0; j < ptEstimate.size(); j++ ) {
945  //std::cout<<" weighting pt: "<< ptEstimate[j] <<std::endl;
946  if ( ptEstimate[j] < 0. ) {
947  // To prevent from blowing up, add 0.1
948  charge -= 1. * (ptEstimate[j]*ptEstimate[j]) / (sptEstimate[j]*sptEstimate[j] ); // weight by relative error on pt
949  } else {
950  charge += 1. * (ptEstimate[j]*ptEstimate[j]) / (sptEstimate[j]*sptEstimate[j] ); // weight by relative error on pt
951  }
952  }
953 
954  // No need to normalize as we want to know only sign ( + or - )
955  if (charge < 0.) {
956  charge = -1.;
957  } else {
958  charge = 1.;
959  }
960 
961  //int n = 0;
962  double weightPtSum = 0.;
963  double sigmaSqr_sum = 0.;
964 
965  // Now, we want to compute average Pt using estimators with "correct" charge
966  // This is to remove biases
967  for ( unsigned j = 0; j < ptEstimate.size(); ++j ) {
968  //if ( (minpt_ratio < 0.5) && (fabs(ptEstimate[j]) < 5.0) ) continue;
969  //if ( ptEstimate[j] * charge > 0. ) {
970  //n++;
971  sigmaSqr_sum += 1.0 / (sptEstimate[j]*sptEstimate[j]);
972  weightPtSum += fabs(ptEstimate[j])/(sptEstimate[j]*sptEstimate[j]);
973  //}
974  }
975  /*
976  if (n < 1) {
977  thePt = defaultMomentum*charge;
978  theSpt = defaultMomentum;
979  return;
980  }
981  */
982  // Compute weighted mean and error
983 
984  thePt = (charge*weightPtSum) / sigmaSqr_sum;
985  theSpt = sqrt( 1.0 / sigmaSqr_sum ) ;
986 
987  //std::cout<<" final weighting : "<< thePt <<" ~ "<< fabs( theSpt/thePt ) <<std::endl;
988 
989  return;
990 }
T sqrt(T t)
Definition: SSEVec.h:18
int j
Definition: DBlmapReader.cc:9
tuple size
Write out results.

Member Data Documentation

const MagneticField* MuonSeedCreator::BField
private

Definition at line 90 of file MuonSeedCreator.h.

Referenced by createSeed(), and setBField().

std::vector<double> MuonSeedCreator::CSC01
private

Definition at line 100 of file MuonSeedCreator.h.

std::vector<double> MuonSeedCreator::CSC01_1
private

Definition at line 137 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC02
private

Definition at line 102 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC03
private

Definition at line 104 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC12
private

Definition at line 101 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC12_1
private

Definition at line 138 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC12_2
private

Definition at line 139 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC12_3
private

Definition at line 140 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC13
private

Definition at line 103 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC13_2
private

Definition at line 141 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC13_3
private

Definition at line 142 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC14
private

Definition at line 105 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC14_3
private

Definition at line 143 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC23
private

Definition at line 106 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC23_1
private

Definition at line 144 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC23_2
private

Definition at line 145 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC24
private

Definition at line 107 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC24_1
private

Definition at line 146 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC34
private

Definition at line 108 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::CSC34_1
private

Definition at line 147 of file MuonSeedCreator.h.

Referenced by estimatePtCSC(), and MuonSeedCreator().

bool MuonSeedCreator::debug
private

Definition at line 87 of file MuonSeedCreator.h.

Referenced by createSeed(), and MuonSeedCreator().

float MuonSeedCreator::defaultMomentum
private
std::vector<double> MuonSeedCreator::DT12
private

Definition at line 93 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT12_1
private

Definition at line 149 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT12_2
private

Definition at line 150 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT13
private

Definition at line 94 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT13_1
private

Definition at line 151 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT13_2
private

Definition at line 152 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT14
private

Definition at line 95 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT14_1
private

Definition at line 153 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT14_2
private

Definition at line 154 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT23
private

Definition at line 96 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT23_1
private

Definition at line 155 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT23_2
private

Definition at line 156 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT24
private

Definition at line 97 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT24_1
private

Definition at line 157 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT24_2
private

Definition at line 158 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT34
private

Definition at line 98 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT34_1
private

Definition at line 159 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::DT34_2
private

Definition at line 160 of file MuonSeedCreator.h.

Referenced by estimatePtDT(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL1213
private

Definition at line 110 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL1222
private

Definition at line 111 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL1232
private

Definition at line 112 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL2213
private

Definition at line 113 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap().

std::vector<double> MuonSeedCreator::OL2222
private

Definition at line 114 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL_1213
private

Definition at line 162 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL_1222
private

Definition at line 163 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL_1232
private

Definition at line 164 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL_2213
private

Definition at line 165 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::OL_2222
private

Definition at line 166 of file MuonSeedCreator.h.

Referenced by estimatePtOverlap(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB10
private

Definition at line 125 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB11
private

Definition at line 126 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB12
private

Definition at line 127 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB20
private

Definition at line 128 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB21
private

Definition at line 129 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB22
private

Definition at line 130 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB30
private

Definition at line 131 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB31
private

Definition at line 132 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB32
private

Definition at line 133 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_10S
private

Definition at line 168 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_11S
private

Definition at line 169 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_12S
private

Definition at line 170 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_20S
private

Definition at line 171 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_21S
private

Definition at line 172 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_22S
private

Definition at line 173 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_30S
private

Definition at line 174 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_31S
private

Definition at line 175 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SMB_32S
private

Definition at line 176 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME11
private

Definition at line 116 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME12
private

Definition at line 117 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME13
private

Definition at line 118 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME21
private

Definition at line 119 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME22
private

Definition at line 120 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME31
private

Definition at line 121 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME32
private

Definition at line 122 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME41
private

Definition at line 123 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME_11S
private

Definition at line 178 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME_12S
private

Definition at line 179 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME_13S
private

Definition at line 180 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME_21S
private

Definition at line 181 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

std::vector<double> MuonSeedCreator::SME_22S
private

Definition at line 182 of file MuonSeedCreator.h.

Referenced by estimatePtSingle(), and MuonSeedCreator().

double MuonSeedCreator::sysError
private

Definition at line 84 of file MuonSeedCreator.h.

Referenced by MuonSeedCreator().

float MuonSeedCreator::theMaxMomentum
private
float MuonSeedCreator::theMinMomentum
private

Definition at line 79 of file MuonSeedCreator.h.

Referenced by createSeed(), and MuonSeedCreator().