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FastPixelHitMatcher Class Reference

#include <FastPixelHitMatcher.h>

Public Types

typedef
TransientTrackingRecHit::ConstRecHitPointer 
ConstRecHitPointer
 
typedef
TransientTrackingRecHit::RecHitContainer 
RecHitContainer
 
typedef
TransientTrackingRecHit::RecHitPointer 
RecHitPointer
 

Public Member Functions

bool checkRZCompatibility (double zCluster, double rCluster, double zVertex, float rzMin, float rzMax, GlobalPoint &theHit, bool forward)
 
std::vector< std::pair
< ConstRecHitPointer,
ConstRecHitPointer > > 
compatibleHits (const GlobalPoint &xmeas, const GlobalPoint &vprim, float energy, std::vector< TrackerRecHit > &theHits)
 
 FastPixelHitMatcher (float, float, float, float, float, float, float, float, float, float, float, float, bool)
 
double getVertex ()
 
bool isASeed (const ParticlePropagator &myElec, const ParticlePropagator &myPosi, const GlobalPoint &theVertex, double rCluster, double zCluster, const TrackerRecHit &hit1, const TrackerRecHit &hit2)
 
bool propagateToLayer (ParticlePropagator &myPart, const GlobalPoint &theVertex, GlobalPoint &theHit, double phimin, double phimax, unsigned layer)
 
void set1stLayer (float ephimin, float ephimax, float pphimin, float pphimax)
 
void set1stLayerZRange (double zmin1, double zmax1)
 
void set2ndLayer (float phimin, float phimax)
 
void setES (const MagneticFieldMap *aFieldMap, const TrackerGeometry *aTrackerGeometry, const GeometricSearchTracker *geomSearchTracker, const TrackerInteractionGeometry *interactionGeometry)
 
double zVertex (double zCluster, double rCluster, GlobalPoint &theHit)
 
virtual ~FastPixelHitMatcher ()
 

Private Attributes

const TrackerInteractionGeometry_theGeometry
 
float ephi1max
 
float ephi1min
 
RecHitContainer hitsInTrack
 
float phi2max
 
float phi2min
 
float pphi1max
 
float pphi1min
 
float r2maxF
 
float r2minF
 
float rMaxI
 
float rMinI
 
bool searchInTIDTEC
 
const MagneticFieldMaptheFieldMap
 
const GeometricSearchTrackertheGeomSearchTracker
 
const MagneticFieldtheMagneticField
 
std::vector< const TrackerLayer * > thePixelLayers
 
const TrackerGeometrytheTrackerGeometry
 
double vertex
 
float z1max
 
float z1min
 
float z2maxB
 
float z2minB
 

Detailed Description

Description: central class for finding compatible hits

Implementation: <Notes on="" implementation>="">

Description: Class to match an ECAL cluster to the pixel hits. Two compatible hits in the pixel layers are required.

Implementation: future redesign

Definition at line 38 of file FastPixelHitMatcher.h.

Member Typedef Documentation

Definition at line 42 of file FastPixelHitMatcher.h.

Definition at line 44 of file FastPixelHitMatcher.h.

Definition at line 43 of file FastPixelHitMatcher.h.

Constructor & Destructor Documentation

FastPixelHitMatcher::FastPixelHitMatcher ( float  ephi1min,
float  ephi1max,
float  pphi1min,
float  pphi1max,
float  phi2min,
float  phi2max,
float  z2minB,
float  z2maxB,
float  r2minF,
float  r2maxF,
float  rMinI,
float  rMaxI,
bool  searchInTIDTEC 
)

Definition at line 30 of file FastPixelHitMatcher.cc.

36  :
42  rMinI(rMinI), rMaxI(rMaxI),
47  _theGeometry(0),
48  thePixelLayers(50,static_cast<TrackerLayer*>(0)),
49  vertex(0.) {}
std::vector< const TrackerLayer * > thePixelLayers
const GeometricSearchTracker * theGeomSearchTracker
const TrackerGeometry * theTrackerGeometry
const TrackerInteractionGeometry * _theGeometry
const MagneticField * theMagneticField
FastPixelHitMatcher::~FastPixelHitMatcher ( )
virtual

Definition at line 51 of file FastPixelHitMatcher.cc.

51 { }

Member Function Documentation

bool FastPixelHitMatcher::checkRZCompatibility ( double  zCluster,
double  rCluster,
double  zVertex,
float  rzMin,
float  rzMax,
GlobalPoint theHit,
bool  forward 
)

Definition at line 321 of file FastPixelHitMatcher.cc.

References PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::z(), and zVertex().

Referenced by isASeed().

326 {
327 
328  // The hit position
329  double zHit = theHit.z();
330  double rHit = theHit.perp();
331 
332  // Compute the intersection of a line joining the cluster position
333  // and the predicted z origin (zVertex) with the layer hit
334  // (returns R for a forward layer, and Z for a barrel layer)
335  double checkRZ = forward ?
336  (zHit-zVertex)/(zCluster-zVertex) * rCluster
337  :
338  zVertex + rHit * (zCluster-zVertex)/rCluster;
339 
340  // This value is then compared to check with the actual hit position
341  // (in R for a forward layer, in Z for a barrel layer)
342 
343  return forward ?
344  checkRZ+rzMin < rHit && rHit < checkRZ+rzMax
345  :
346  checkRZ+rzMin < zHit && zHit < checkRZ+rzMax;
347 
348 }
T perp() const
Definition: PV3DBase.h:72
double zVertex(double zCluster, double rCluster, GlobalPoint &theHit)
T z() const
Definition: PV3DBase.h:64
std::vector< std::pair< FastPixelHitMatcher::ConstRecHitPointer, FastPixelHitMatcher::ConstRecHitPointer > > FastPixelHitMatcher::compatibleHits ( const GlobalPoint xmeas,
const GlobalPoint vprim,
float  energy,
std::vector< TrackerRecHit > &  theHits 
)

Definition at line 81 of file FastPixelHitMatcher.cc.

References GenericTransientTrackingRecHit::build(), gather_cfg::cout, isASeed(), PV3DBase< T, PVType, FrameType >::mag(), PV3DBase< T, PVType, FrameType >::perp(), ParticlePropagator::propagateToNominalVertex(), query::result, theFieldMap, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by FastElectronSeedGenerator::addASeedToThisCluster().

84  {
85 
86  std::vector< std::pair<FastPixelHitMatcher::ConstRecHitPointer,
87  FastPixelHitMatcher::ConstRecHitPointer> > result;
88 #ifdef FAMOS_DEBUG
89  std::cout << "[FastPixelHitMatcher::compatibleHits] entering .. " << std::endl;
90 #endif
91 
92  double zCluster = thePos.z();
93  double rCluster = thePos.perp();
94 
95  // The cluster inferred energy-momentum
96  double theLength = thePos.mag();
97  XYZTLorentzVector theMom(thePos.x(), thePos.y(), thePos.z(), theLength);
98  theMom *= energy / theLength;
99  XYZTLorentzVector theVert(thePos.x(),thePos.y(),thePos.z(),0.);
100  XYZTLorentzVector theNominalVertex(theVertex.x(), theVertex.y(), theVertex.z(), 0.);
101 
102  // The corresponding RawParticles (to be propagated for e- and e+
103  ParticlePropagator myElec(theMom,theVert,-1.,theFieldMap);
104  ParticlePropagator myPosi(theMom,theVert,+1.,theFieldMap);
105 #ifdef FAMOS_DEBUG
106  std::cout << "elec/posi before propagation " << std::endl << myElec << std::endl << myPosi << std::endl;
107 #endif
108 
109  // Propagate the e- and the e+ hypothesis to the nominal vertex
110  // by modifying the pT direction in an appropriate manner.
111  myElec.propagateToNominalVertex(theNominalVertex);
112  myPosi.propagateToNominalVertex(theNominalVertex);
113 #ifdef FAMOS_DEBUG
114  std::cout << "elec/posi after propagation " << std::endl << myElec << std::endl << myPosi << std::endl;
115 #endif
116 
117  // Look for an appropriate see in the pixel detector
118  bool thereIsASeed = false;
119  unsigned nHits = theHits.size();
120 
121  for ( unsigned firstHit=0; firstHit<nHits-1; ++firstHit ) {
122  for ( unsigned secondHit=firstHit+1; secondHit<nHits; ++secondHit ) {
123 
124  // Is there a seed associated to this pair of Pixel hits?
125  thereIsASeed = isASeed(myElec,myPosi,theVertex,
126  rCluster,zCluster,
127  theHits[firstHit],
128  theHits[secondHit]);
129 
130 #ifdef FAMOS_DEBUG
131  std::cout << "Is there a seed with hits " << firstHit << " & "<< secondHit << "? " << thereIsASeed << std::endl;
132 #endif
133  if ( !thereIsASeed ) continue;
134 
135  ConstRecHitPointer theFirstHit =
136  GenericTransientTrackingRecHit::build(theHits[firstHit].geomDet(),
137  theHits[firstHit].hit());
138  ConstRecHitPointer theSecondHit =
139  GenericTransientTrackingRecHit::build(theHits[secondHit].geomDet(),
140  theHits[secondHit].hit());
141  result.push_back(std::pair<
142  FastPixelHitMatcher::ConstRecHitPointer,
143  FastPixelHitMatcher::ConstRecHitPointer>(theFirstHit,theSecondHit));
144 
145  }
146  }
147 
148  return result;
149 }
TransientTrackingRecHit::ConstRecHitPointer ConstRecHitPointer
static RecHitPointer build(const GeomDet *geom, const TrackingRecHit *rh)
TransientTrackingRecHit::ConstRecHitPointer ConstRecHitPointer
tuple result
Definition: query.py:137
bool isASeed(const ParticlePropagator &myElec, const ParticlePropagator &myPosi, const GlobalPoint &theVertex, double rCluster, double zCluster, const TrackerRecHit &hit1, const TrackerRecHit &hit2)
const MagneticFieldMap * theFieldMap
tuple cout
Definition: gather_cfg.py:121
math::XYZTLorentzVector XYZTLorentzVector
Definition: RawParticle.h:15
double FastPixelHitMatcher::getVertex ( )
inline

Definition at line 62 of file FastPixelHitMatcher.h.

References vertex.

Referenced by FastElectronSeedGenerator::addASeedToThisCluster().

62 { return vertex; }
bool FastPixelHitMatcher::isASeed ( const ParticlePropagator myElec,
const ParticlePropagator myPosi,
const GlobalPoint theVertex,
double  rCluster,
double  zCluster,
const TrackerRecHit hit1,
const TrackerRecHit hit2 
)

Definition at line 151 of file FastPixelHitMatcher.cc.

References checkRZCompatibility(), gather_cfg::cout, TrackerRecHit::cylinderNumber(), ephi1max, ephi1min, TrackerRecHit::globalPosition(), TrackerRecHit::isOnTheSameLayer(), phi2max, phi2min, pphi1max, pphi1min, propagateToLayer(), r2maxF, r2minF, rMaxI, rMinI, TrackerRecHit::subDetId(), vertex, z1max, z1min, z2maxB, z2minB, and zVertex().

Referenced by compatibleHits().

157  {
158 
159  // Check that the two hits are not on the same layer
160  if ( hit2.isOnTheSameLayer(hit1) ) return false;
161 #ifdef FAMOS_DEBUG
162  std::cout << "isASeed: The two hits are not on the same layer - OK " << std::endl;
163 #endif
164 
165  // Check that the first hit is on PXB or PXD
166  if ( hit1.subDetId() > 2 ) return false;
167 #ifdef FAMOS_DEBUG
168  std::cout << "isASeed: The first hits is on the pixel detector " << std::endl;
169 #endif
170 
171  // Impose the track to originate from zVertex = 0. and check the
172  // compatibility with the first hit (beam spot constraint)
173  GlobalPoint firstHit = hit1.globalPosition();
174  bool rzok = checkRZCompatibility(zCluster, rCluster, 0., z1min, z1max, firstHit, hit1.subDetId()>1);
175 #ifdef FAMOS_DEBUG
176  std::cout << "isASeed: rzok (1) = " << rzok << std::endl;
177 #endif
178  if ( !rzok ) return false;
179 
180  // Refine the Z vertex by imposing the track to pass through the first RecHit,
181  // and check the compatibility with the second rechit
182  GlobalPoint secondHit = hit2.globalPosition();
183  rzok = false;
184 
185  // The orgin Z vertex for thet track passing through the first rechit
186  vertex = zVertex(zCluster, rCluster, firstHit);
187 
188  // Compute R (forward) or Z (barrel) predicted for the second hit and check compatibility
189  if ( hit2.subDetId() == 1 ) {
190  rzok = checkRZCompatibility(zCluster, rCluster, vertex, z2minB, z2maxB, secondHit, false);
191  } else if ( hit2.subDetId() == 2 ) {
192  rzok = checkRZCompatibility(zCluster, rCluster, vertex, r2minF, r2maxF, secondHit, true);
193  } else {
194  rzok = checkRZCompatibility(zCluster, rCluster, vertex, rMinI, rMaxI, secondHit, true);
195  }
196 #ifdef FAMOS_DEBUG
197  std::cout << "isASeed: rzok (2) = " << rzok << std::endl;
198 #endif
199  if ( !rzok ) return false;
200 
201  // Propagate the inferred electron (positron) to the first layer,
202  // check the compatibility with the first hit, and propagate back
203  // to the nominal vertex with the hit constraint
204  ParticlePropagator elec(myElec);
205  ParticlePropagator posi(myPosi);
206 #ifdef FAMOS_DEBUG
207  std::cout << "isASeed: elec1 to be propagated to first layer" << std::endl;
208 #endif
209  bool elec1 = propagateToLayer(elec,theVertex,firstHit,
211 #ifdef FAMOS_DEBUG
212  std::cout << "isASeed: posi1 to be propagated to first layer" << std::endl;
213 #endif
214  bool posi1 = propagateToLayer(posi,theVertex,firstHit,
216 
217 #ifdef FAMOS_DEBUG
218  std::cout << "isASeed: elec1 / posi1 " << elec1 << " " << posi1 << std::endl;
219 #endif
220  // Neither the electron not the positron hypothesis work...
221  if ( !elec1 && !posi1 ) return false;
222 
223  // Otherwise, propagate to the second layer, check the compatibility
224  // with the second hit and propagate back to the nominal vertex with
225  // the hit constraint
226 #ifdef FAMOS_DEBUG
227  std::cout << "isASeed: elec2 to be propagated to second layer" << std::endl;
228 #endif
229  bool elec2 = elec1 && propagateToLayer(elec,theVertex,secondHit,
231 
232 #ifdef FAMOS_DEBUG
233  std::cout << "isASeed: posi2 to be propagated to second layer" << std::endl;
234 #endif
235  bool posi2 = posi1 && propagateToLayer(posi,theVertex,secondHit,
237 
238 #ifdef FAMOS_DEBUG
239  std::cout << "isASeed: elec2 / posi2 " << elec2 << " " << posi2 << std::endl;
240 #endif
241  if ( !elec2 && !posi2 ) return false;
242 
243  return true;
244 
245 }
unsigned int cylinderNumber() const
The global layer number in the nested cylinder geometry.
Definition: TrackerRecHit.h:90
GlobalPoint globalPosition() const
The global position.
Definition: TrackerRecHit.h:99
bool isOnTheSameLayer(const TrackerRecHit &other) const
Check if two hits are on the same layer of the same subdetector.
double zVertex(double zCluster, double rCluster, GlobalPoint &theHit)
bool propagateToLayer(ParticlePropagator &myPart, const GlobalPoint &theVertex, GlobalPoint &theHit, double phimin, double phimax, unsigned layer)
bool checkRZCompatibility(double zCluster, double rCluster, double zVertex, float rzMin, float rzMax, GlobalPoint &theHit, bool forward)
unsigned int subDetId() const
The subdet Id.
Definition: TrackerRecHit.h:81
tuple cout
Definition: gather_cfg.py:121
bool FastPixelHitMatcher::propagateToLayer ( ParticlePropagator myPart,
const GlobalPoint theVertex,
GlobalPoint theHit,
double  phimin,
double  phimax,
unsigned  layer 
)

Definition at line 248 of file FastPixelHitMatcher.cc.

References gather_cfg::cout, M_PI, PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), BaseParticlePropagator::propagate(), ParticlePropagator::propagateToNominalVertex(), BaseParticlePropagator::setPropagationConditions(), RawParticle::setVertex(), summarizeEdmComparisonLogfiles::success, thePixelLayers, vertex, RawParticle::vertex(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by isASeed().

252  {
253 
254  // Set the z position of the particle to the predicted one
255  XYZTLorentzVector theNominalVertex(theVertex.x(), theVertex.y(), vertex, 0.);
256  myPart.setVertex(theNominalVertex);
257 #ifdef FAMOS_DEBUG
258  std::cout << "propagateToLayer: propagateToLayer: Before propagation (0) " << myPart << std::endl;
259 #endif
260 
261  // Propagate the inferred electron (positron) to the first layer
262  // Use the radius (barrel) or the z (forward) of the hit instead
263  // of the inaccurate layer radius and z.
264  double rCyl = thePixelLayers[layer]->forward() ? 999. : theHit.perp();
265  double zCyl = thePixelLayers[layer]->forward() ? fabs(theHit.z()) : 999.;
266  BaseParticlePropagator* myBasePart = (BaseParticlePropagator*)(&myPart);
267  myBasePart->setPropagationConditions(rCyl,zCyl);
268  // myPart.setPropagationConditions(*(thePixelLayers[layer]));
269 
270  // bool success = myPart.propagateToBoundSurface(*(thePixelLayers[layer]));
271  bool success = myPart.propagate();
272 #ifdef FAMOS_DEBUG
273  std::cout << "propagateToLayer: Success ? " << success << std::endl;
274  std::cout << "propagateToLayer: After propagation (1) " << myPart << std::endl;
275  std::cout << "propagateToLayer: The hit " << theHit << std::endl;
276 #endif
277 
278  // Check that propagated particle is within the proper phi range.
279  if ( success ) {
280  double dphi = myPart.vertex().phi() - theHit.phi();
281  if ( dphi < -M_PI )
282  dphi = dphi + 2.*M_PI;
283  else if ( dphi > M_PI )
284  dphi = dphi - 2.*M_PI;
285 #ifdef FAMOS_DEBUG
286  std::cout << "propagateToLayer: Phi range ? " << phimin << " < " << dphi << " < " << phimax << std::endl;
287 #endif
288  if ( dphi < phimin || dphi > phimax ) success = false;
289  }
290 
291  // Impose the track to go through the hit and propagate back to
292  // the nominal vertex
293  if ( success ) {
294  myPart.setVertex( XYZTLorentzVector(theHit.x(), theHit.y(), theHit.z(), 0.) );
295  myPart.propagateToNominalVertex(theNominalVertex);
296 #ifdef FAMOS_DEBUG
297  std::cout << "propagateToLayer: After propagation (2) " << myPart << std::endl;
298 #endif
299  }
300 
301  return success;
302 
303 }
T perp() const
Definition: PV3DBase.h:72
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
T y() const
Definition: PV3DBase.h:63
void setPropagationConditions(double r, double z, bool firstLoop=true)
Set the propagation characteristics (rCyl, zCyl and first loop only)
std::vector< const TrackerLayer * > thePixelLayers
T z() const
Definition: PV3DBase.h:64
#define M_PI
const XYZTLorentzVector & vertex() const
the vertex fourvector
Definition: RawParticle.h:285
bool propagateToNominalVertex(const XYZTLorentzVector &hit2=XYZTLorentzVector(0., 0., 0., 0.))
tuple cout
Definition: gather_cfg.py:121
T x() const
Definition: PV3DBase.h:62
void setVertex(const XYZTLorentzVector &vtx)
set the vertex
Definition: RawParticle.h:288
math::XYZTLorentzVector XYZTLorentzVector
Definition: RawParticle.h:15
void FastPixelHitMatcher::set1stLayer ( float  ephimin,
float  ephimax,
float  pphimin,
float  pphimax 
)
inline

Definition at line 64 of file FastPixelHitMatcher.h.

References ephi1max, ephi1min, pphi1max, and pphi1min.

Referenced by FastElectronSeedGenerator::addASeedToThisCluster().

65  {
66 
67  ephi1min = ephimin;
68  ephi1max = ephimax;
69  pphi1min = pphimin;
70  pphi1max = pphimax;
71 
72  }
void FastPixelHitMatcher::set1stLayerZRange ( double  zmin1,
double  zmax1 
)
inline

Definition at line 105 of file FastPixelHitMatcher.h.

References z1max, and z1min.

Referenced by FastElectronSeedGenerator::run().

105  {
106  z1max = zmax1;
107  z1min = zmin1;
108  }
void FastPixelHitMatcher::set2ndLayer ( float  phimin,
float  phimax 
)
inline
void FastPixelHitMatcher::setES ( const MagneticFieldMap aFieldMap,
const TrackerGeometry aTrackerGeometry,
const GeometricSearchTracker geomSearchTracker,
const TrackerInteractionGeometry interactionGeometry 
)

Definition at line 54 of file FastPixelHitMatcher.cc.

References _theGeometry, TrackerInteractionGeometry::cylinderBegin(), TrackerInteractionGeometry::cylinderEnd(), theFieldMap, theGeomSearchTracker, thePixelLayers, and theTrackerGeometry.

Referenced by FastElectronSeedGenerator::setupES().

57  {
58 
59  // initialize the tracker geometry and the magnetic field map
60  theTrackerGeometry = aTrackerGeometry;
61  //theMagneticField = aMagField;
62  theGeomSearchTracker = geomSearchTracker;
63  _theGeometry = interactionGeometry;
64  theFieldMap = aFieldMap;
65 
66  // Initialize (if not already done) the simplified magnetic field geometry
67  // MagneticFieldMap::instance( theMagneticField, _theGeometry );
68 
69  // The pixel layers in the simplified geometry
70  unsigned layer = 1;
71  std::list<TrackerLayer>::const_iterator cyliter = _theGeometry->cylinderBegin();
72  for ( ; cyliter != _theGeometry->cylinderEnd() ; ++cyliter ) {
73  if ( layer != cyliter->layerNumber() ) continue;
74  thePixelLayers[layer++] = &(*cyliter);
75  }
76 
77 }
std::list< TrackerLayer >::const_iterator cylinderEnd() const
Returns the last pointer in the cylinder list.
std::vector< const TrackerLayer * > thePixelLayers
const GeometricSearchTracker * theGeomSearchTracker
const MagneticFieldMap * theFieldMap
const TrackerGeometry * theTrackerGeometry
std::list< TrackerLayer >::const_iterator cylinderBegin() const
Returns the first pointer in the cylinder list.
const TrackerInteractionGeometry * _theGeometry
double FastPixelHitMatcher::zVertex ( double  zCluster,
double  rCluster,
GlobalPoint theHit 
)

Definition at line 307 of file FastPixelHitMatcher.cc.

References PV3DBase< T, PVType, FrameType >::perp(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by checkRZCompatibility(), and isASeed().

310 {
311 
312  // Refine the Z vertex by imposing the track to pass through the RecHit
313  double pxHitz = theHit.z();
314  double pxHitr = theHit.perp();
315  return pxHitz - pxHitr*(zCluster-pxHitz)/(rCluster-pxHitr);
316 
317 }
T perp() const
Definition: PV3DBase.h:72
T z() const
Definition: PV3DBase.h:64

Member Data Documentation

const TrackerInteractionGeometry* FastPixelHitMatcher::_theGeometry
private

Definition at line 126 of file FastPixelHitMatcher.h.

Referenced by setES().

float FastPixelHitMatcher::ephi1max
private

Definition at line 114 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayer().

float FastPixelHitMatcher::ephi1min
private

Definition at line 114 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayer().

RecHitContainer FastPixelHitMatcher::hitsInTrack
private

Definition at line 112 of file FastPixelHitMatcher.h.

float FastPixelHitMatcher::phi2max
private

Definition at line 116 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set2ndLayer().

float FastPixelHitMatcher::phi2min
private

Definition at line 116 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set2ndLayer().

float FastPixelHitMatcher::pphi1max
private

Definition at line 115 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayer().

float FastPixelHitMatcher::pphi1min
private

Definition at line 115 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayer().

float FastPixelHitMatcher::r2maxF
private

Definition at line 119 of file FastPixelHitMatcher.h.

Referenced by isASeed().

float FastPixelHitMatcher::r2minF
private

Definition at line 119 of file FastPixelHitMatcher.h.

Referenced by isASeed().

float FastPixelHitMatcher::rMaxI
private

Definition at line 120 of file FastPixelHitMatcher.h.

Referenced by isASeed().

float FastPixelHitMatcher::rMinI
private

Definition at line 120 of file FastPixelHitMatcher.h.

Referenced by isASeed().

bool FastPixelHitMatcher::searchInTIDTEC
private

Definition at line 121 of file FastPixelHitMatcher.h.

const MagneticFieldMap* FastPixelHitMatcher::theFieldMap
private

Definition at line 127 of file FastPixelHitMatcher.h.

Referenced by compatibleHits(), and setES().

const GeometricSearchTracker* FastPixelHitMatcher::theGeomSearchTracker
private

Definition at line 125 of file FastPixelHitMatcher.h.

Referenced by setES().

const MagneticField* FastPixelHitMatcher::theMagneticField
private

Definition at line 124 of file FastPixelHitMatcher.h.

std::vector<const TrackerLayer*> FastPixelHitMatcher::thePixelLayers
private

Definition at line 128 of file FastPixelHitMatcher.h.

Referenced by propagateToLayer(), and setES().

const TrackerGeometry* FastPixelHitMatcher::theTrackerGeometry
private

Definition at line 123 of file FastPixelHitMatcher.h.

Referenced by setES().

double FastPixelHitMatcher::vertex
private

Definition at line 129 of file FastPixelHitMatcher.h.

Referenced by getVertex(), isASeed(), and propagateToLayer().

float FastPixelHitMatcher::z1max
private

Definition at line 117 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayerZRange().

float FastPixelHitMatcher::z1min
private

Definition at line 117 of file FastPixelHitMatcher.h.

Referenced by isASeed(), and set1stLayerZRange().

float FastPixelHitMatcher::z2maxB
private

Definition at line 118 of file FastPixelHitMatcher.h.

Referenced by isASeed().

float FastPixelHitMatcher::z2minB
private

Definition at line 118 of file FastPixelHitMatcher.h.

Referenced by isASeed().