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ME0SegFit.cc
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1 // ------------------------- //
2 // ME0SegFit.cc
3 // Created: 11.05.2015
4 // Based on CSCSegFit.cc
5 // ------------------------- //
6 
10 
13 
14 
15 void ME0SegFit::fit(void) {
16  if ( fitdone() ) return; // don't redo fit unnecessarily
17  short n = nhits();
18  switch ( n ) {
19  case 1:
20  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fit] - cannot fit just 1 hit!!";
21  break;
22  case 2:
23  fit2();
24  break;
25  case 3:
26  case 4:
27  case 5:
28  case 6:
29  fitlsq();
30  break;
31  default:
32  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fit] - cannot fit more than 6 hits!!";
33  }
34 }
35 
36 void ME0SegFit::fit2(void) {
37 
38  // Just join the two points
39  // Equation of straight line between (x1, y1) and (x2, y2) in xy-plane is
40  // y = mx + c
41  // with m = (y2-y1)/(x2-x1)
42  // and c = (y1*x2-x2*y1)/(x2-x1)
43 
44 
45  // 1) Check whether hits are on the same layer
46  // -------------------------------------------
47  ME0SetOfHits::const_iterator ih = hits_.begin();
48 
49  ME0DetId d1 = DetId((*ih)->rawId());
50  int il1 = d1.layer();
51  const ME0RecHit& h1 = (**ih);
52  ++ih;
53  ME0DetId d2 = DetId((*ih)->rawId());
54  int il2 = d2.layer();
55  const ME0RecHit& h2 = (**ih);
56 
57  // Skip if on same layer, but should be impossible :)
58  if (il1 == il2) {
59  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit:fit2] - 2 hits on same layer!!";
60  return;
61  }
62 
63 
64  // 2) Global Positions of hit 1 and 2 and
65  // Local Positions of hit 1 and 2 w.r.t. reference ME0 Eta Partition
66  // ---------------------------------------------------------------------
67  const ME0EtaPartition* roll1 = me0etapartition(d1);
68  GlobalPoint h1glopos = roll1->toGlobal(h1.localPosition());
69  const ME0EtaPartition* roll2 = me0etapartition(d2);
70  GlobalPoint h2glopos = roll2->toGlobal(h2.localPosition());
71 
72  // We want hit wrt first me0 eta partition
73  // ( = reference m00 eta partition)
74  // (and local z will be != 0)
75  LocalPoint h1pos = refme0etapart()->toLocal(h1glopos);
76  LocalPoint h2pos = refme0etapart()->toLocal(h2glopos);
77 
78 
79  // 3) Now make straight line between the two points in local coords
80  // ----------------------------------------------------------------
81  float dz = h2pos.z()-h1pos.z();
82  if(dz != 0.0) {
83  uslope_ = ( h2pos.x() - h1pos.x() ) / dz ;
84  vslope_ = ( h2pos.y() - h1pos.y() ) / dz ;
85  }
86 
87  float uintercept = ( h1pos.x()*h2pos.z() - h2pos.x()*h1pos.z() ) / dz;
88  float vintercept = ( h1pos.y()*h2pos.z() - h2pos.y()*h1pos.z() ) / dz;
89  intercept_ = LocalPoint( uintercept, vintercept, 0.);
90 
91  setOutFromIP();
92 
93  //@@ NOT SURE WHAT IS SENSIBLE FOR THESE...
94  chi2_ = 0.;
95  ndof_ = 0;
96 
97  fitdone_ = true;
98 }
99 
100 
101 void ME0SegFit::fitlsq(void) {
102 
103  // Linear least-squares fit to up to 6 ME0 rechits, one per layer in a ME0 chamber.
104  // Comments adapted from Tim Cox' comments in the original ME0SegAlgoSK algorithm.
105 
106  // Fit to the local x, y rechit coordinates in z projection
107  // The strip measurement controls the precision of x
108  // The wire measurement controls the precision of y.
109  // Typical precision: u (strip, sigma~200um), v (wire, sigma~1cm)
110 
111  // Set up the normal equations for the least-squares fit as a matrix equation
112 
113  // We have a vector of measurements m, which is a 2n x 1 dim matrix
114  // The transpose mT is (u1, v1, u2, v2, ..., un, vn) where
115  // ui is the strip-associated measurement and
116  // vi is the wire-associated measurement
117  // for a given rechit i.
118 
119  // The fit is to
120  // u = u0 + uz * z
121  // v = v0 + vz * z
122  // where u0, uz, v0, vz are the parameters to be obtained from the fit.
123 
124  // These are contained in a vector p which is a 4x1 dim matrix, and
125  // its transpose pT is (u0, v0, uz, vz). Note the ordering!
126 
127  // The covariance matrix for each pair of measurements is 2 x 2 and
128  // the inverse of this is the error matrix E.
129  // The error matrix for the whole set of n measurements is a diagonal
130  // matrix with diagonal elements the individual 2 x 2 error matrices
131  // (because the inverse of a diagonal matrix is a diagonal matrix
132  // with each element the inverse of the original.)
133 
134  // In function 'weightMatrix()', the variable 'matrix' is filled with this
135  // block-diagonal overall covariance matrix. Then 'matrix' is inverted to the
136  // block-diagonal error matrix, and returned.
137 
138  // Define the matrix A as
139  // 1 0 z1 0
140  // 0 1 0 z1
141  // 1 0 z2 0
142  // 0 1 0 z2
143  // .. .. .. ..
144  // 1 0 zn 0
145  // 0 1 0 zn
146 
147  // This matrix A is set up and returned by function 'derivativeMatrix()'.
148 
149  // Then the normal equations are described by the matrix equation
150  //
151  // (AT E A)p = (AT E)m
152  //
153  // where AT is the transpose of A.
154 
155  // Call the combined matrix on the LHS, M, and that on the RHS, B:
156  // M p = B
157 
158  // We solve this for the parameter vector, p.
159  // The elements of M and B then involve sums over the hits
160 
161  // The covariance matrix of the parameters is obtained by
162  // (AT E A)^-1 calculated in 'covarianceMatrix()'.
163 
164 
165  // NOTE
166  // We need local position of a RecHit w.r.t. the CHAMBER
167  // and the RecHit itself only knows its local position w.r.t.
168  // the LAYER, so we must explicitly transform global position.
169 
170 
171  SMatrix4 M; // 4x4, init to 0
172  SVector4 B; // 4x1, init to 0;
173 
174  ME0SetOfHits::const_iterator ih = hits_.begin();
175 
176  // LogDebug :: Loop over the TrackingRecHits and print the ME0 Hits
177  for (ih = hits_.begin(); ih != hits_.end(); ++ih)
178  {
179  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fitlsq] - looping over ME0RecHits";
180  const ME0RecHit& hit = (**ih);
181  ME0DetId d = ME0DetId(hit.rawId());
182  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fitlsq] - Tracking RecHit in detid ("<<d.rawId()<<")";
183  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fitlsq] - ME0DetId ("<<ME0DetId(d.rawId())<<")";
184  }
185 
186  // Loop over the ME0RecHits and make small (2x2) matrices used to fill the blockdiagonal covariance matrix E^-1
187  for (ih = hits_.begin(); ih != hits_.end(); ++ih) {
188  const ME0RecHit& hit = (**ih);
189  ME0DetId d = DetId(hit.rawId());
190  const ME0EtaPartition* roll = me0etapartition(d);
191  GlobalPoint gp = roll->toGlobal(hit.localPosition());
192  LocalPoint lp = refme0etapart()->toLocal(gp);
193 
194  // LogDebug
195  #ifdef EDM_ML_DEBUG // have lines below only compiled when in debug mode
196  std::stringstream lpss; lpss<<lp; std::string lps = lpss.str();
197  std::stringstream gpss; gpss<<gp; std::string gps = gpss.str();
198  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fitlsq] - Tracking RecHit global position "<<std::setw(30)<<gps<<" and local position "<<std::setw(30)<<lps
199  <<" wrt reference ME0 eta partition "<<refme0etapart()->id().rawId()<<" = "<<refme0etapart()->id();
200  #endif
201 
202  // Local position of hit w.r.t. chamber
203  double u = lp.x();
204  double v = lp.y();
205  double z = lp.z();
206 
207  // Covariance matrix of local errors
208  SMatrixSym2 IC; // 2x2, init to 0
209 
210  IC(0,0) = hit.localPositionError().xx();
211  IC(1,1) = hit.localPositionError().yy();
212  //@@ NOT SURE WHICH OFF-DIAGONAL ELEMENT MUST BE DEFINED BUT (1,0) WORKS
213  //@@ (and SMatrix enforces symmetry)
214  IC(1,0) = hit.localPositionError().xy();
215  // IC(0,1) = IC(1,0);
216 
217  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::fit] 2x2 covariance matrix for this ME0RecHit :: [[" << IC(0,0) <<", "<< IC(0,1) <<"]["<< IC(1,0) <<","<<IC(1,1)<<"]]";
218 
219  // Invert covariance matrix (and trap if it fails!)
220  bool ok = IC.Invert();
221  if ( !ok ) {
222  edm::LogVerbatim("ME0Segment|ME0SegFit") << "[ME0SegFit::fit] Failed to invert covariance matrix: \n" << IC;
223  // return ok; //@@ SHOULD PASS THIS BACK TO CALLER?
224  }
225 
226  M(0,0) += IC(0,0);
227  M(0,1) += IC(0,1);
228  M(0,2) += IC(0,0) * z;
229  M(0,3) += IC(0,1) * z;
230  B(0) += u * IC(0,0) + v * IC(0,1);
231 
232  M(1,0) += IC(1,0);
233  M(1,1) += IC(1,1);
234  M(1,2) += IC(1,0) * z;
235  M(1,3) += IC(1,1) * z;
236  B(1) += u * IC(1,0) + v * IC(1,1);
237 
238  M(2,0) += IC(0,0) * z;
239  M(2,1) += IC(0,1) * z;
240  M(2,2) += IC(0,0) * z * z;
241  M(2,3) += IC(0,1) * z * z;
242  B(2) += ( u * IC(0,0) + v * IC(0,1) ) * z;
243 
244  M(3,0) += IC(1,0) * z;
245  M(3,1) += IC(1,1) * z;
246  M(3,2) += IC(1,0) * z * z;
247  M(3,3) += IC(1,1) * z * z;
248  B(3) += ( u * IC(1,0) + v * IC(1,1) ) * z;
249 
250  }
251 
252  SVector4 p;
253  bool ok = M.Invert();
254  if (!ok ){
255  edm::LogVerbatim("ME0Segment|ME0SegFit") << "[ME0SegFit::fit] Failed to invert matrix: \n" << M;
256  // return ok; //@@ SHOULD PASS THIS BACK TO CALLER?
257  }
258  else {
259  p = M * B;
260  }
261 
262  LogTrace("ME0SegFit") << "[ME0SegFit::fit] p = "
263  << p(0) << ", " << p(1) << ", " << p(2) << ", " << p(3);
264 
265  // fill member variables (note origin has local z = 0)
266  // intercept_
267  intercept_ = LocalPoint(p(0), p(1), 0.);
268 
269  // localdir_ - set so segment points outwards from IP
270  uslope_ = p(2);
271  vslope_ = p(3);
272  setOutFromIP();
273 
274  // calculate chi2 of fit
275  setChi2( );
276 
277  // flag fit has been done
278  fitdone_ = true;
279 
280 }
281 
282 
283 
284 void ME0SegFit::setChi2(void) {
285 
286  double chsq = 0.;
287 
288  ME0SetOfHits::const_iterator ih;
289  for (ih = hits_.begin(); ih != hits_.end(); ++ih) {
290 
291  const ME0RecHit& hit = (**ih);
292  ME0DetId d = ME0DetId(hit.rawId());
293  const ME0EtaPartition* roll = me0etapartition(d);
294  GlobalPoint gp = roll->toGlobal(hit.localPosition());
295  LocalPoint lp = refme0etapart()->toLocal(gp);
296 
297  double u = lp.x();
298  double v = lp.y();
299  double z = lp.z();
300 
301  double du = intercept_.x() + uslope_ * z - u;
302  double dv = intercept_.y() + vslope_ * z - v;
303 
304  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::setChi2] u, v, z = " << u << ", " << v << ", " << z;
305 
306  SMatrixSym2 IC; // 2x2, init to 0
307 
308  IC(0,0) = hit.localPositionError().xx();
309  // IC(0,1) = hit.localPositionError().xy();
310  IC(1,0) = hit.localPositionError().xy();
311  IC(1,1) = hit.localPositionError().yy();
312  // IC(1,0) = IC(0,1);
313 
314  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::setChi2] IC before = \n" << IC;
315 
316  // Invert covariance matrix
317  bool ok = IC.Invert();
318  if (!ok ){
319  edm::LogVerbatim("ME0Segment|ME0SegFit") << "[ME0SegFit::setChi2] Failed to invert covariance matrix: \n" << IC;
320  // return ok;
321  }
322  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::setChi2] IC after = \n" << IC;
323  chsq += du*du*IC(0,0) + 2.*du*dv*IC(0,1) + dv*dv*IC(1,1);
324  }
325 
326  // fill member variables
327  chi2_ = chsq;
328  ndof_ = 2.*hits_.size() - 4;
329 
330  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::setChi2] chi2 = " << chi2_ << "/" << ndof_ << " dof";
331 
332 }
333 
334 
335 
336 
338 
339  bool ok = true;
340 
341  SMatrixSym12 matrix = ROOT::Math::SMatrixIdentity(); // 12x12, init to 1's on diag
342 
343  int row = 0;
344 
345  for (ME0SetOfHits::const_iterator it = hits_.begin(); it != hits_.end(); ++it) {
346 
347  const ME0RecHit& hit = (**it);
348 
349 // Note scaleXError allows rescaling the x error if necessary
350 
351  matrix(row, row) = scaleXError()*hit.localPositionError().xx();
352  matrix(row, row+1) = hit.localPositionError().xy();
353  ++row;
354  matrix(row, row-1) = hit.localPositionError().xy();
355  matrix(row, row) = hit.localPositionError().yy();
356  ++row;
357  }
358 
359  ok = matrix.Invert(); // invert in place
360  if ( !ok ) {
361  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::weightMatrix] Failed to invert matrix: \n" << matrix;
362  // return ok; //@@ SHOULD PASS THIS BACK TO CALLER?
363  }
364  return matrix;
365 }
366 
367 
368 
369 
371 
372  SMatrix12by4 matrix; // 12x4, init to 0
373  int row = 0;
374 
375  for( ME0SetOfHits::const_iterator it = hits_.begin(); it != hits_.end(); ++it) {
376 
377  const ME0RecHit& hit = (**it);
378  ME0DetId d = ME0DetId(hit.rawId());
379  const ME0EtaPartition* roll = me0etapartition(d);
380  GlobalPoint gp = roll->toGlobal(hit.localPosition());
381  LocalPoint lp = refme0etapart()->toLocal(gp);
382  float z = lp.z();
383 
384  matrix(row, 0) = 1.;
385  matrix(row, 2) = z;
386  ++row;
387  matrix(row, 1) = 1.;
388  matrix(row, 3) = z;
389  ++row;
390  }
391  return matrix;
392 }
393 
394 
396  // Set direction of segment to point from IP outwards
397  // (Incorrect for particles not coming from IP, of course.)
398 
399  double dxdz = uslope_;
400  double dydz = vslope_;
401  double dz = 1./sqrt(1. + dxdz*dxdz + dydz*dydz);
402  double dx = dz*dxdz;
403  double dy = dz*dydz;
404  LocalVector localDir(dx,dy,dz);
405 
406  // localDir sometimes needs a sign flip
407  // Examine its direction and origin in global z: to point outward
408  // the localDir should always have same sign as global z...
409 
410  double globalZpos = ( refme0etapart()->toGlobal( intercept_ ) ).z();
411  double globalZdir = ( refme0etapart()->toGlobal( localDir ) ).z();
412  double directionSign = globalZpos * globalZdir;
413  localdir_ = (directionSign * localDir ).unit();
414 }
415 
416 
417 
419 
422  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::covarianceMatrix] weights matrix W: \n" << weights;
423  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::covarianceMatrix] derivatives matrix A: \n" << A;
424 
425  // (AT W A)^-1
426  // e.g. See http://www.phys.ufl.edu/~avery/fitting.html, part I
427 
428  bool ok;
429  SMatrixSym4 result = ROOT::Math::SimilarityT(A, weights);
430  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::covarianceMatrix] (AT W A): \n" << result;
431  ok = result.Invert(); // inverts in place
432  if ( !ok ) {
433  edm::LogVerbatim("ME0Segment|ME0SegFit") << "[ME0SegFit::calculateError] Failed to invert matrix: \n" << result;
434  // return ok; //@@ SHOULD PASS THIS BACK TO CALLER?
435  }
436  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::covarianceMatrix] (AT W A)^-1: \n" << result;
437 
438  // reorder components to match TrackingRecHit interface (ME0Segment isa TrackingRecHit)
439  // i.e. slopes first, then positions
440  AlgebraicSymMatrix flipped = flipErrors( result );
441 
442  return flipped;
443 }
444 
445 
447 
448  // The ME0Segment needs the error matrix re-arranged to match
449  // parameters in order (uz, vz, u0, v0)
450  // where uz, vz = slopes, u0, v0 = intercepts
451 
452  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::flipErrors] input: \n" << a;
453 
454  AlgebraicSymMatrix hold(4, 0. );
455 
456  for ( short j=0; j!=4; ++j) {
457  for (short i=0; i!=4; ++i) {
458  hold(i+1,j+1) = a(i,j); // SMatrix counts from 0, AlgebraicMatrix from 1
459  }
460  }
461 
462  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::flipErrors] after copy:";
463  edm::LogVerbatim("ME0SegFit") << "(" << hold(1,1) << " " << hold(1,2) << " " << hold(1,3) << " " << hold(1,4);
464  edm::LogVerbatim("ME0SegFit") << " " << hold(2,1) << " " << hold(2,2) << " " << hold(2,3) << " " << hold(2,4);
465  edm::LogVerbatim("ME0SegFit") << " " << hold(3,1) << " " << hold(3,2) << " " << hold(3,3) << " " << hold(3,4);
466  edm::LogVerbatim("ME0SegFit") << " " << hold(4,1) << " " << hold(4,2) << " " << hold(4,3) << " " << hold(4,4) << ")";
467 
468  // errors on slopes into upper left
469  hold(1,1) = a(2,2);
470  hold(1,2) = a(2,3);
471  hold(2,1) = a(3,2);
472  hold(2,2) = a(3,3);
473 
474  // errors on positions into lower right
475  hold(3,3) = a(0,0);
476  hold(3,4) = a(0,1);
477  hold(4,3) = a(1,0);
478  hold(4,4) = a(1,1);
479 
480  // must also interchange off-diagonal elements of off-diagonal 2x2 submatrices
481  hold(4,1) = a(1,2);
482  hold(3,2) = a(0,3);
483  hold(2,3) = a(3,0); // = a(0,3)
484  hold(1,4) = a(2,1); // = a(1,2)
485 
486  edm::LogVerbatim("ME0SegFit") << "[ME0SegFit::flipErrors] after flip:";
487  edm::LogVerbatim("ME0SegFit") << "(" << hold(1,1) << " " << hold(1,2) << " " << hold(1,3) << " " << hold(1,4);
488  edm::LogVerbatim("ME0SegFit") << " " << hold(2,1) << " " << hold(2,2) << " " << hold(2,3) << " " << hold(2,4);
489  edm::LogVerbatim("ME0SegFit") << " " << hold(3,1) << " " << hold(3,2) << " " << hold(3,3) << " " << hold(3,4);
490  edm::LogVerbatim("ME0SegFit") << " " << hold(4,1) << " " << hold(4,2) << " " << hold(4,3) << " " << hold(4,4) << ")";
491 
492  return hold;
493 }
494 
495 float ME0SegFit::xfit( float z ) const {
496  //@@ ADD THIS TO EACH ACCESSOR OF FIT RESULTS?
497  // if ( !fitdone() ) fit();
498  return intercept_.x() + uslope_ * z;
499 }
500 
501 float ME0SegFit::yfit( float z ) const {
502  return intercept_.y() + vslope_ * z;
503 }
504 
505 float ME0SegFit::xdev( float x, float z ) const {
506  return intercept_.x() + uslope_ * z - x;
507 }
508 
509 float ME0SegFit::ydev( float y, float z ) const {
510  return intercept_.y() + vslope_ * z - y;
511 }
512 
513 float ME0SegFit::Rdev(float x, float y, float z) const {
514  return sqrt ( xdev(x,z)*xdev(x,z) + ydev(y,z)*ydev(y,z) );
515 }
516 
ROOT::Math::SVector< double, 4 > SVector4
Definition: ME0SegFit.h:59
int i
Definition: DBlmapReader.cc:9
float xx() const
Definition: LocalError.h:24
bool fitdone() const
Definition: ME0SegFit.h:113
float ydev(float y, float z) const
Definition: ME0SegFit.cc:509
double_binary B
Definition: DDStreamer.cc:234
float vslope_
Definition: ME0SegFit.h:142
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:54
LocalVector localdir_
Definition: ME0SegFit.h:144
ROOT::Math::SMatrix< double, 4, 4, ROOT::Math::MatRepSym< double, 4 > > SMatrixSym4
Definition: ME0SegFit.h:53
T y() const
Definition: PV3DBase.h:63
LocalPoint toLocal(const GlobalPoint &gp) const
Conversion to the R.F. of the GeomDet.
Definition: GeomDet.h:69
ROOT::Math::SMatrix< double, 4 > SMatrix4
Definition: ME0SegFit.h:52
float float float z
virtual LocalError localPositionError() const
Return the 3-dimensional error on the local position.
Definition: ME0RecHit.h:53
ROOT::Math::SMatrix< double, 12, 12, ROOT::Math::MatRepSym< double, 12 > > SMatrixSym12
Definition: ME0SegFit.h:46
tuple result
Definition: mps_fire.py:84
ROOT::Math::SMatrix< double, 2, 2, ROOT::Math::MatRepSym< double, 2 > > SMatrixSym2
Definition: ME0SegFit.h:56
uint32_t rawId() const
get the raw id
Definition: DetId.h:43
tuple d
Definition: ztail.py:151
T x() const
Cartesian x coordinate.
float Rdev(float x, float y, float z) const
Definition: ME0SegFit.cc:513
float xy() const
Definition: LocalError.h:25
AlgebraicSymMatrix flipErrors(const SMatrixSym4 &)
Definition: ME0SegFit.cc:446
const ME0EtaPartition * me0etapartition(uint32_t id) const
Definition: ME0SegFit.h:111
void fitlsq(void)
Definition: ME0SegFit.cc:101
bool fitdone_
Definition: ME0SegFit.h:149
size_t nhits(void) const
Definition: ME0SegFit.h:106
float yy() const
Definition: LocalError.h:26
string unit
Definition: csvLumiCalc.py:46
T sqrt(T t)
Definition: SSEVec.h:18
ME0DetId id() const
T z() const
Definition: PV3DBase.h:64
AlgebraicSymMatrix covarianceMatrix(void)
Definition: ME0SegFit.cc:418
double chi2_
Definition: ME0SegFit.h:145
virtual LocalPoint localPosition() const
Return the 3-dimensional local position.
Definition: ME0RecHit.h:47
int j
Definition: DBlmapReader.cc:9
ME0SetOfHits hits_
Definition: ME0SegFit.h:140
const ME0EtaPartition * refme0etapart() const
Definition: ME0SegFit.h:112
ROOT::Math::SMatrix< double, 12, 4 > SMatrix12by4
Definition: ME0SegFit.h:49
SMatrix12by4 derivativeMatrix(void)
Definition: ME0SegFit.cc:370
double scaleXError(void) const
Definition: ME0SegFit.h:105
void fit2(void)
Definition: ME0SegFit.cc:36
#define LogTrace(id)
Definition: DetId.h:18
float xfit(float z) const
Definition: ME0SegFit.cc:495
SMatrixSym12 weightMatrix(void)
Definition: ME0SegFit.cc:337
void setOutFromIP(void)
Definition: ME0SegFit.cc:395
void fit(void)
Definition: ME0SegFit.cc:15
double a
Definition: hdecay.h:121
LocalPoint intercept_
Definition: ME0SegFit.h:143
CLHEP::HepSymMatrix AlgebraicSymMatrix
int ndof_
Definition: ME0SegFit.h:146
Local3DPoint LocalPoint
Definition: LocalPoint.h:11
int layer() const
Layer id: each chamber has six layers of chambers: layer 1 is the inner layer and layer 6 is the oute...
Definition: ME0DetId.h:56
float yfit(float z) const
Definition: ME0SegFit.cc:501
T x() const
Definition: PV3DBase.h:62
float uslope_
Definition: ME0SegFit.h:141
id_type rawId() const
float xdev(float x, float z) const
Definition: ME0SegFit.cc:505
void setChi2(void)
Definition: ME0SegFit.cc:284