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CSCSegAlgoRU.cc
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1 
8 #include "CSCSegAlgoRU.h"
9 #include "CSCSegFit.h"
15 #include <algorithm>
16 #include <cmath>
17 #include <iostream>
18 #include <memory>
19 
20 #include <string>
21 
22 CSCSegAlgoRU::CSCSegAlgoRU(const edm::ParameterSet& ps) : CSCSegmentAlgorithm(ps), myName("CSCSegAlgoRU") {
23  doCollisions = ps.getParameter<bool>("doCollisions");
24  enlarge = ps.getParameter<bool>("enlarge");
25  chi2_str_ = ps.getParameter<double>("chi2_str");
26  chi2Norm_2D_ = ps.getParameter<double>("chi2Norm_2D_");
27  dRMax = ps.getParameter<double>("dRMax");
28  dPhiMax = ps.getParameter<double>("dPhiMax");
29  dRIntMax = ps.getParameter<double>("dRIntMax");
30  dPhiIntMax = ps.getParameter<double>("dPhiIntMax");
31  chi2Max = ps.getParameter<double>("chi2Max");
32  wideSeg = ps.getParameter<double>("wideSeg");
33  minLayersApart = ps.getParameter<int>("minLayersApart");
34 
35  LogDebug("CSC") << myName << " has algorithm cuts set to: \n"
36  << "--------------------------------------------------------------------\n"
37  << "dRMax = " << dRMax << '\n'
38  << "dPhiMax = " << dPhiMax << '\n'
39  << "dRIntMax = " << dRIntMax << '\n'
40  << "dPhiIntMax = " << dPhiIntMax << '\n'
41  << "chi2Max = " << chi2Max << '\n'
42  << "wideSeg = " << wideSeg << '\n'
43  << "minLayersApart = " << minLayersApart << std::endl;
44 
45  //reset the thresholds for non-collision data
46  if (!doCollisions) {
47  dRMax = 2.0;
48  dPhiMax = 2 * dPhiMax;
49  dRIntMax = 2 * dRIntMax;
50  dPhiIntMax = 2 * dPhiIntMax;
52  chi2_str_ = 100;
53  chi2Max = 2 * chi2Max;
54  }
55 }
56 
57 std::vector<CSCSegment> CSCSegAlgoRU::buildSegments(const CSCChamber* aChamber,
58  const ChamberHitContainer& urechits) const {
59  ChamberHitContainer rechits = urechits;
60  LayerIndex layerIndex(rechits.size());
61  int recHits_per_layer[6] = {0, 0, 0, 0, 0, 0};
62  //skip events with high multiplicity of hits
63  if (rechits.size() > 150) {
64  return std::vector<CSCSegment>();
65  }
66  int iadd = 0;
67  for (unsigned int i = 0; i < rechits.size(); i++) {
68  recHits_per_layer[rechits[i]->cscDetId().layer() - 1]++; //count rh per chamber
69  layerIndex[i] = rechits[i]->cscDetId().layer();
70  }
71  double z1 = aChamber->layer(1)->position().z();
72  double z6 = aChamber->layer(6)->position().z();
73  if (std::abs(z1) > std::abs(z6)) {
74  reverse(layerIndex.begin(), layerIndex.end());
75  reverse(rechits.begin(), rechits.end());
76  }
77  if (rechits.size() < 2) {
78  return std::vector<CSCSegment>();
79  }
80  // We have at least 2 hits. We intend to try all possible pairs of hits to start
81  // segment building. 'All possible' means each hit lies on different layers in the chamber.
82  // after all same size segs are build we get rid of the overcrossed segments using the chi2 criteria
83  // the hits from the segs that are left are marked as used and are not added to segs in future iterations
84  // the hits from 3p segs are marked as used separately in order to try to assamble them in longer segments
85  // in case there is a second pass
86  // Choose first hit (as close to IP as possible) h1 and second hit
87  // (as far from IP as possible) h2 To do this we iterate over hits
88  // in the chamber by layer - pick two layers. Then we
89  // iterate over hits within each of these layers and pick h1 and h2
90  // these. If they are 'close enough' we build an empty
91  // segment. Then try adding hits to this segment.
92  // Initialize flags that a given hit has been allocated to a segment
93  BoolContainer used(rechits.size(), false);
94  BoolContainer used3p(rechits.size(), false);
95  // This is going to point to fits to hits, and its content will be used to create a CSCSegment
96  AlgoState aState;
97  aState.aChamber = aChamber;
98  aState.doCollisions = doCollisions;
99  aState.enlarge = enlarge;
100  aState.dRMax = dRMax;
101  aState.dPhiMax = dPhiMax;
102  aState.dRIntMax = dRIntMax;
103  aState.dPhiIntMax = dPhiIntMax;
104  aState.chi2Norm_2D_ = chi2Norm_2D_;
105  aState.chi2_str_ = chi2_str_;
106  aState.chi2Max = chi2Max;
107 
108  int scale_factor = 1;
109  if (aState.enlarge)
110  scale_factor = 2;
111 
112  // Define buffer for segments we build
113  std::vector<CSCSegment> segments;
115  ChamberHitContainerCIt ie = rechits.end();
116  // Possibly allow 3 passes, second widening scale factor for cuts, third for segments from displaced vertices
117  aState.windowScale = 1.; // scale factor for cuts
118  bool search_disp = false;
119  aState.strip_iadd = 1;
120  aState.chi2D_iadd = 1;
121  int npass = (wideSeg > 1.) ? 3 : 2;
122  for (int ipass = 0; ipass < npass; ++ipass) {
123  if (aState.windowScale > 1.) {
124  iadd = 1;
125  aState.strip_iadd = 2 * scale_factor;
126  aState.chi2D_iadd = 2 * scale_factor;
127  if (aState.enlarge) {
128  aState.chi2Max = 2 * chi2Max;
129  if (rechits.size() <= 12)
130  iadd = 0; //allow 3 hit segments for low hit multiplicity chambers
131  }
132  }
133 
134  int used_rh = 0;
135  for (ChamberHitContainerCIt i1 = ib; i1 != ie; ++i1) {
136  if (used[i1 - ib])
137  used_rh++;
138  }
139 
140  //change the tresholds if it's time to look for displaced mu segments
141  if (aState.doCollisions && search_disp &&
142  int(rechits.size() - used_rh) >
143  2) { //check if there are enough recHits left to build a segment from displaced vertices
144  aState.doCollisions = false;
145  aState.windowScale = 1.; // scale factor for cuts
146  aState.dRMax = scale_factor * 2.0;
147  aState.dPhiMax = scale_factor * 2 * aState.dPhiMax;
148  aState.dRIntMax = scale_factor * 2 * aState.dRIntMax;
149  aState.dPhiIntMax = scale_factor * 2 * aState.dPhiIntMax;
150  aState.chi2Norm_2D_ = scale_factor * 5 * aState.chi2Norm_2D_;
151  aState.chi2_str_ = scale_factor * 100;
152  aState.chi2Max = scale_factor * 2 * aState.chi2Max;
153  } else {
154  search_disp = false; //make sure the flag is off
155  }
156 
157  for (unsigned int n_seg_min = 6u; n_seg_min > 2u + iadd; --n_seg_min) {
158  BoolContainer common_used(rechits.size(), false);
159  std::array<BoolContainer, 120> common_used_it = {};
160  for (unsigned int i = 0; i < common_used_it.size(); i++) {
161  common_used_it[i] = common_used;
162  }
163  ChamberHitContainer best_proto_segment[120];
164  float min_chi[120] = {9999};
165  int common_it = 0;
166  bool first_proto_segment = true;
167  for (ChamberHitContainerCIt i1 = ib; i1 != ie; ++i1) {
168  bool segok = false;
169  //skip if rh is used and the layer tat has big rh multiplicity(>25RHs)
170  if (used[i1 - ib] || recHits_per_layer[int(layerIndex[i1 - ib]) - 1] > 25 ||
171  (n_seg_min == 3 && used3p[i1 - ib]))
172  continue;
173  int layer1 = layerIndex[i1 - ib];
174  const CSCRecHit2D* h1 = *i1;
175  for (ChamberHitContainerCIt i2 = ie - 1; i2 != i1; --i2) {
176  if (used[i2 - ib] || recHits_per_layer[int(layerIndex[i2 - ib]) - 1] > 25 ||
177  (n_seg_min == 3 && used3p[i2 - ib]))
178  continue;
179  int layer2 = layerIndex[i2 - ib];
180  if ((abs(layer2 - layer1) + 1) < int(n_seg_min))
181  break; //decrease n_seg_min
182  const CSCRecHit2D* h2 = *i2;
183  if (areHitsCloseInR(aState, h1, h2) && areHitsCloseInGlobalPhi(aState, h1, h2)) {
184  aState.proto_segment.clear();
185  if (!addHit(aState, h1, layer1))
186  continue;
187  if (!addHit(aState, h2, layer2))
188  continue;
189  // Can only add hits if already have a segment
190  if (aState.sfit)
191  tryAddingHitsToSegment(aState, rechits, used, layerIndex, i1, i2);
192  segok = isSegmentGood(aState, rechits);
193  if (segok) {
194  if (aState.proto_segment.size() > n_seg_min) {
195  baseline(aState, n_seg_min);
196  updateParameters(aState);
197  }
198  if (aState.sfit->chi2() > aState.chi2Norm_2D_ * aState.chi2D_iadd ||
199  aState.proto_segment.size() < n_seg_min)
200  aState.proto_segment.clear();
201  if (!aState.proto_segment.empty()) {
202  updateParameters(aState);
203  //add same-size overcrossed protosegments to the collection
204  if (first_proto_segment) {
205  flagHitsAsUsed(aState, rechits, common_used_it[0]);
206  min_chi[0] = aState.sfit->chi2();
207  best_proto_segment[0] = aState.proto_segment;
208  first_proto_segment = false;
209  } else { //for the rest of found proto_segments
210  common_it++;
211  flagHitsAsUsed(aState, rechits, common_used_it[common_it]);
212  min_chi[common_it] = aState.sfit->chi2();
213  best_proto_segment[common_it] = aState.proto_segment;
214  ChamberHitContainerCIt hi, iu, ik;
215  int iter = common_it;
216  for (iu = ib; iu != ie; ++iu) {
217  for (hi = aState.proto_segment.begin(); hi != aState.proto_segment.end(); ++hi) {
218  if (*hi == *iu) {
219  int merge_nr = -1;
220  for (int k = 0; k < iter + 1; k++) {
221  if (common_used_it[k][iu - ib] == true) {
222  if (merge_nr != -1) {
223  //merge the k and merge_nr collections of flaged hits into the merge_nr collection and unmark the k collection hits
224  for (ik = ib; ik != ie; ++ik) {
225  if (common_used_it[k][ik - ib] == true) {
226  common_used_it[merge_nr][ik - ib] = true;
227  common_used_it[k][ik - ib] = false;
228  }
229  }
230  //change best_protoseg if min_chi_2 is smaller
231  if (min_chi[k] < min_chi[merge_nr]) {
232  min_chi[merge_nr] = min_chi[k];
233  best_proto_segment[merge_nr] = best_proto_segment[k];
234  best_proto_segment[k].clear();
235  min_chi[k] = 9999;
236  }
237  common_it--;
238  } else {
239  merge_nr = k;
240  }
241  } //if(common_used[k][iu-ib] == true)
242  } //for k
243  } //if
244  } //for proto_seg
245  } //for rec_hits
246  } //else
247  } //proto seg not empty
248  }
249  } // h1 & h2 close
250  if (segok)
251  break;
252  } // i2
253  } // i1
254 
255  //add the reconstructed segments
256  for (int j = 0; j < common_it + 1; j++) {
257  aState.proto_segment = best_proto_segment[j];
258  best_proto_segment[j].clear();
259  //SKIP empty proto-segments
260  if (aState.proto_segment.empty())
261  continue;
262  updateParameters(aState);
263  // Create an actual CSCSegment - retrieve all info from the fit
264  CSCSegment temp(aState.sfit->hits(),
265  aState.sfit->intercept(),
266  aState.sfit->localdir(),
267  aState.sfit->covarianceMatrix(),
268  aState.sfit->chi2());
269  aState.sfit = nullptr;
270  segments.push_back(temp);
271  //if the segment has 3 hits flag them as used in a particular way
272  if (aState.proto_segment.size() == 3) {
273  flagHitsAsUsed(aState, rechits, used3p);
274  } else {
275  flagHitsAsUsed(aState, rechits, used);
276  }
277  aState.proto_segment.clear();
278  }
279  } //for n_seg_min
280 
281  if (search_disp) {
282  //reset params and flags for the next chamber
283  search_disp = false;
284  aState.doCollisions = true;
285  aState.dRMax = 2.0;
286  aState.chi2_str_ = 100;
287  aState.dPhiMax = 0.5 * aState.dPhiMax / scale_factor;
288  aState.dRIntMax = 0.5 * aState.dRIntMax / scale_factor;
289  aState.dPhiIntMax = 0.5 * aState.dPhiIntMax / scale_factor;
290  aState.chi2Norm_2D_ = 0.2 * aState.chi2Norm_2D_ / scale_factor;
291  aState.chi2Max = 0.5 * aState.chi2Max / scale_factor;
292  }
293 
294  std::vector<CSCSegment>::iterator it = segments.begin();
295  bool good_segs = false;
296  while (it != segments.end()) {
297  if ((*it).nRecHits() > 3) {
298  good_segs = true;
299  break;
300  }
301  ++it;
302  }
303  if (good_segs &&
304  aState.doCollisions) { // only change window if not enough good segments were found (bool can be changed to int if a >0 number of good segs is required)
305  search_disp = true;
306  continue; //proceed to search the segs from displaced vertices
307  }
308 
309  // Increase cut windows by factor of wideSeg only for collisions
310  if (!aState.doCollisions && !search_disp)
311  break;
312  aState.windowScale = wideSeg;
313  } // ipass
314 
315  //get rid of enchansed 3p segments
316  std::vector<CSCSegment>::iterator it = segments.begin();
317  while (it != segments.end()) {
318  if ((*it).nRecHits() == 3) {
319  bool found_common = false;
320  const std::vector<CSCRecHit2D>& theseRH = (*it).specificRecHits();
321  for (ChamberHitContainerCIt i1 = ib; i1 != ie; ++i1) {
322  if (used[i1 - ib] && used3p[i1 - ib]) {
323  const CSCRecHit2D* sh1 = *i1;
324  CSCDetId id = sh1->cscDetId();
325  int sh1layer = id.layer();
326  int RH_centerid = sh1->nStrips() / 2;
327  int RH_centerStrip = sh1->channels(RH_centerid);
328  int RH_wg = sh1->hitWire();
329  std::vector<CSCRecHit2D>::const_iterator sh;
330  for (sh = theseRH.begin(); sh != theseRH.end(); ++sh) {
331  CSCDetId idRH = sh->cscDetId();
332  //find segment hit coord
333  int shlayer = idRH.layer();
334  int SegRH_centerid = sh->nStrips() / 2;
335  int SegRH_centerStrip = sh->channels(SegRH_centerid);
336  int SegRH_wg = sh->hitWire();
337  if (sh1layer == shlayer && SegRH_centerStrip == RH_centerStrip && SegRH_wg == RH_wg) {
338  //remove the enchansed 3p segment
339  segments.erase(it, (it + 1));
340  found_common = true;
341  break;
342  }
343  } //theserh
344  }
345  if (found_common)
346  break; //current seg has already been erased
347  } //camber hits
348  if (!found_common)
349  ++it;
350  } //its a 3p seg
351  else {
352  ++it; //go to the next seg
353  }
354  } //while
355  // Give the segments to the CSCChamber
356  return segments;
357 } //build segments
358 
361  const BoolContainer& used,
362  const LayerIndex& layerIndex,
364  const ChamberHitContainerCIt i2) const {
365  // Iterate over the layers with hits in the chamber
366  // Skip the layers containing the segment endpoints
367  // Test each hit on the other layers to see if it is near the segment
368  // If it is, see whether there is already a hit on the segment from the same layer
369  // - if so, and there are more than 2 hits on the segment, copy the segment,
370  // replace the old hit with the new hit. If the new segment chi2 is better
371  // then replace the original segment with the new one (by swap)
372  // - if not, copy the segment, add the hit. If the new chi2/dof is still satisfactory
373  // then replace the original segment with the new one (by swap)
375  ChamberHitContainerCIt ie = rechits.end();
376  for (ChamberHitContainerCIt i = ib; i != ie; ++i) {
377  int layer = layerIndex[i - ib];
378  if (hasHitOnLayer(aState, layer) && aState.proto_segment.size() <= 2)
379  continue;
380  if (layerIndex[i - ib] == layerIndex[i1 - ib] || layerIndex[i - ib] == layerIndex[i2 - ib] || used[i - ib])
381  continue;
382 
383  const CSCRecHit2D* h = *i;
384  if (isHitNearSegment(aState, h)) {
385  // Don't consider alternate hits on layers holding the two starting points
386  if (hasHitOnLayer(aState, layer)) {
387  if (aState.proto_segment.size() <= 2)
388  continue;
389  compareProtoSegment(aState, h, layer);
390  } else {
391  increaseProtoSegment(aState, h, layer, aState.chi2D_iadd);
392  }
393  } // h & seg close
394  } // i
395 }
396 
397 bool CSCSegAlgoRU::areHitsCloseInR(const AlgoState& aState, const CSCRecHit2D* h1, const CSCRecHit2D* h2) const {
398  float maxWG_width[10] = {0, 0, 4.1, 5.69, 2.49, 5.06, 2.49, 5.06, 1.87, 5.06};
399  CSCDetId id = h1->cscDetId();
400  int iStn = id.iChamberType() - 1;
401  //find maxWG_width for ME11 (tilt = 29deg)
402  int wg_num = h2->hitWire();
403  if (iStn == 0 || iStn == 1) {
404  if (wg_num == 1) {
405  maxWG_width[0] = 9.25;
406  maxWG_width[1] = 9.25;
407  }
408  if (wg_num > 1 && wg_num < 48) {
409  maxWG_width[0] = 3.14;
410  maxWG_width[1] = 3.14;
411  }
412  if (wg_num == 48) {
413  maxWG_width[0] = 10.75;
414  maxWG_width[1] = 10.75;
415  }
416  }
417  const CSCLayer* l1 = aState.aChamber->layer(h1->cscDetId().layer());
418  GlobalPoint gp1 = l1->toGlobal(h1->localPosition());
419  const CSCLayer* l2 = aState.aChamber->layer(h2->cscDetId().layer());
420  GlobalPoint gp2 = l2->toGlobal(h2->localPosition());
421  //find z to understand the direction
422  float h1z = gp1.z();
423  float h2z = gp2.z();
424  //switch off the IP check for non collisions case
425  if (!aState.doCollisions) {
426  h1z = 1;
427  h2z = 1;
428  }
429 
430  if (aState.enlarge) {
431  return (gp2.perp() > ((gp1.perp() - aState.dRMax * aState.strip_iadd * maxWG_width[iStn]) * h2z) / h1z &&
432  gp2.perp() < ((gp1.perp() + aState.dRMax * aState.strip_iadd * maxWG_width[iStn]) * h2z) / h1z)
433  ? true
434  : false;
435 
436  } else {
437  return (gp2.perp() > ((gp1.perp() - aState.dRMax * maxWG_width[iStn]) * h2z) / h1z &&
438  gp2.perp() < ((gp1.perp() + aState.dRMax * maxWG_width[iStn]) * h2z) / h1z)
439  ? true
440  : false;
441  }
442 }
443 
445  const CSCRecHit2D* h1,
446  const CSCRecHit2D* h2) const {
447  float strip_width[10] = {0.003878509,
448  0.002958185,
449  0.002327105,
450  0.00152552,
451  0.00465421,
452  0.002327105,
453  0.00465421,
454  0.002327105,
455  0.00465421,
456  0.002327105}; //in rad
457  const CSCLayer* l1 = aState.aChamber->layer(h1->cscDetId().layer());
458  GlobalPoint gp1 = l1->toGlobal(h1->localPosition());
459  const CSCLayer* l2 = aState.aChamber->layer(h2->cscDetId().layer());
460  GlobalPoint gp2 = l2->toGlobal(h2->localPosition());
461  float err_stpos_h1 = h1->errorWithinStrip();
462  float err_stpos_h2 = h2->errorWithinStrip();
463  CSCDetId id = h1->cscDetId();
464  int iStn = id.iChamberType() - 1;
465  float dphi_incr = 0;
466  if (err_stpos_h1 > 0.25 * strip_width[iStn] || err_stpos_h2 > 0.25 * strip_width[iStn])
467  dphi_incr = 0.5 * strip_width[iStn];
468  float dphi12 = deltaPhi(gp1.barePhi(), gp2.barePhi());
469  return (fabs(dphi12) < (aState.dPhiMax * aState.strip_iadd + dphi_incr)) ? true : false; // +v
470 }
471 
472 bool CSCSegAlgoRU::isHitNearSegment(const AlgoState& aState, const CSCRecHit2D* h) const {
473  // Is hit near segment?
474  // Requires deltaphi and deltaR within ranges specified in parameter set.
475  // Note that to make intuitive cuts on delta(phi) one must work in
476  // phi range (-pi, +pi] not [0, 2pi)
477  float strip_width[10] = {0.003878509,
478  0.002958185,
479  0.002327105,
480  0.00152552,
481  0.00465421,
482  0.002327105,
483  0.00465421,
484  0.002327105,
485  0.00465421,
486  0.002327105}; //in rad
487  const CSCLayer* l1 = aState.aChamber->layer((*(aState.proto_segment.begin()))->cscDetId().layer());
488  GlobalPoint gp1 = l1->toGlobal((*(aState.proto_segment.begin()))->localPosition());
489  const CSCLayer* l2 = aState.aChamber->layer((*(aState.proto_segment.begin() + 1))->cscDetId().layer());
490  GlobalPoint gp2 = l2->toGlobal((*(aState.proto_segment.begin() + 1))->localPosition());
491  float err_stpos_h1 = (*(aState.proto_segment.begin()))->errorWithinStrip();
492  float err_stpos_h2 = (*(aState.proto_segment.begin() + 1))->errorWithinStrip();
493  const CSCLayer* l = aState.aChamber->layer(h->cscDetId().layer());
494  GlobalPoint hp = l->toGlobal(h->localPosition());
495  float err_stpos_h = h->errorWithinStrip();
496  float hphi = hp.phi(); // in (-pi, +pi]
497  if (hphi < 0.)
498  hphi += 2. * M_PI; // into range [0, 2pi)
499  float sphi = phiAtZ(aState, hp.z()); // in [0, 2*pi)
500  float phidif = sphi - hphi;
501  if (phidif < 0.)
502  phidif += 2. * M_PI; // into range [0, 2pi)
503  if (phidif > M_PI)
504  phidif -= 2. * M_PI; // into range (-pi, pi]
505  SVector6 r_glob;
506  CSCDetId id = h->cscDetId();
507  int iStn = id.iChamberType() - 1;
508  float dphi_incr = 0;
509  float pos_str = 1;
510  //increase dPhi cut if the hit is on the edge of the strip
511  float stpos = (*h).positionWithinStrip();
512  bool centr_str = false;
513  if (iStn != 0 && iStn != 1) {
514  if (stpos > -0.25 && stpos < 0.25)
515  centr_str = true;
516  }
517  if (err_stpos_h1 < 0.25 * strip_width[iStn] || err_stpos_h2 < 0.25 * strip_width[iStn] ||
518  err_stpos_h < 0.25 * strip_width[iStn]) {
519  dphi_incr = 0.5 * strip_width[iStn];
520  } else {
521  if (centr_str)
522  pos_str = 1.3;
523  }
524  r_glob((*(aState.proto_segment.begin()))->cscDetId().layer() - 1) = gp1.perp();
525  r_glob((*(aState.proto_segment.begin() + 1))->cscDetId().layer() - 1) = gp2.perp();
526  float R = hp.perp();
527  int layer = h->cscDetId().layer();
528  float r_interpolated = fit_r_phi(aState, r_glob, layer);
529  float dr = fabs(r_interpolated - R);
530  float maxWG_width[10] = {0, 0, 4.1, 5.69, 2.49, 5.06, 2.49, 5.06, 1.87, 5.06};
531  //find maxWG_width for ME11 (tilt = 29deg)
532  int wg_num = h->hitWire();
533  if (iStn == 0 || iStn == 1) {
534  if (wg_num == 1) {
535  maxWG_width[0] = 9.25;
536  maxWG_width[1] = 9.25;
537  }
538  if (wg_num > 1 && wg_num < 48) {
539  maxWG_width[0] = 3.14;
540  maxWG_width[1] = 3.14;
541  }
542  if (wg_num == 48) {
543  maxWG_width[0] = 10.75;
544  maxWG_width[1] = 10.75;
545  }
546  }
547 
548  if (aState.enlarge) {
549  return (fabs(phidif) < aState.dPhiIntMax * aState.strip_iadd * pos_str + dphi_incr &&
550  fabs(dr) < aState.dRIntMax * aState.strip_iadd * maxWG_width[iStn])
551  ? true
552  : false;
553 
554  } else {
555  return (fabs(phidif) < aState.dPhiIntMax * aState.strip_iadd * pos_str + dphi_incr &&
556  fabs(dr) < aState.dRIntMax * maxWG_width[iStn])
557  ? true
558  : false;
559  }
560 }
561 
562 float CSCSegAlgoRU::phiAtZ(const AlgoState& aState, float z) const {
563  if (!aState.sfit)
564  return 0.;
565  // Returns a phi in [ 0, 2*pi )
566  const CSCLayer* l1 = aState.aChamber->layer((*(aState.proto_segment.begin()))->cscDetId().layer());
567  GlobalPoint gp = l1->toGlobal(aState.sfit->intercept());
568  GlobalVector gv = l1->toGlobal(aState.sfit->localdir());
569  float x = gp.x() + (gv.x() / gv.z()) * (z - gp.z());
570  float y = gp.y() + (gv.y() / gv.z()) * (z - gp.z());
571  float phi = atan2(y, x);
572  if (phi < 0.f)
573  phi += 2. * M_PI;
574  return phi;
575 }
576 
577 bool CSCSegAlgoRU::isSegmentGood(const AlgoState& aState, const ChamberHitContainer& rechitsInChamber) const {
578  // If the chamber has 20 hits or fewer, require at least 3 hits on segment
579  // If the chamber has >20 hits require at least 4 hits
580  // If it's the second cycle of the builder and there are <= 12 hits in chamber, require at least 3 hits on segment
581  //@@ THESE VALUES SHOULD BECOME PARAMETERS?
582  bool ok = false;
583  unsigned int iadd = (rechitsInChamber.size() > 20) ? 1 : 0;
584  if (aState.windowScale > 1.) {
585  iadd = 1;
586  if (rechitsInChamber.size() <= 12 && aState.enlarge)
587  iadd = 0;
588  }
589  if (aState.proto_segment.size() >= 3 + iadd)
590  ok = true;
591  return ok;
592 }
593 
595  const ChamberHitContainer& rechitsInChamber,
596  BoolContainer& used) const {
597  // Flag hits on segment as used
598  ChamberHitContainerCIt ib = rechitsInChamber.begin();
600  for (hi = aState.proto_segment.begin(); hi != aState.proto_segment.end(); ++hi) {
601  for (iu = ib; iu != rechitsInChamber.end(); ++iu) {
602  if (*hi == *iu)
603  used[iu - ib] = true;
604  }
605  }
606 }
607 
608 bool CSCSegAlgoRU::addHit(AlgoState& aState, const CSCRecHit2D* aHit, int layer) const {
609  // Return true if hit was added successfully
610  // (and then parameters are updated).
611  // Return false if there is already a hit on the same layer, or insert failed.
612  ChamberHitContainer::const_iterator it;
613  for (it = aState.proto_segment.begin(); it != aState.proto_segment.end(); it++)
614  if (((*it)->cscDetId().layer() == layer) && (aHit != (*it)))
615  return false;
616  aState.proto_segment.push_back(aHit);
617  // make a fit
618  updateParameters(aState);
619  return true;
620 }
621 
623  // Delete input CSCSegFit, create a new one and make the fit
624  // delete sfit;
625  aState.sfit = std::make_unique<CSCSegFit>(aState.aChamber, aState.proto_segment);
626  aState.sfit->fit();
627 }
628 
629 float CSCSegAlgoRU::fit_r_phi(const AlgoState& aState, const SVector6& points, int layer) const {
630  //find R or Phi on the given layer using the given points for the interpolation
631  float Sx = 0;
632  float Sy = 0;
633  float Sxx = 0;
634  float Sxy = 0;
635  for (int i = 1; i < 7; i++) {
636  if (points(i - 1) == 0.)
637  continue;
638  Sy = Sy + (points(i - 1));
639  Sx = Sx + i;
640  Sxx = Sxx + (i * i);
641  Sxy = Sxy + ((i)*points(i - 1));
642  }
643  float delta = 2 * Sxx - Sx * Sx;
644  float intercept = (Sxx * Sy - Sx * Sxy) / delta;
645  float slope = (2 * Sxy - Sx * Sy) / delta;
646  return (intercept + slope * layer);
647 }
648 
649 void CSCSegAlgoRU::baseline(AlgoState& aState, int n_seg_min) const {
650  int nhits = aState.proto_segment.size();
651  //initialise vectors for strip position and error within strip
652  SVector6 sp;
653  SVector6 se;
654  unsigned int init_size = aState.proto_segment.size();
656  buffer.clear();
657  buffer.reserve(init_size);
658  while (buffer.size() < init_size) {
659  ChamberHitContainer::iterator min;
660  int min_layer = 10;
661  for (ChamberHitContainer::iterator k = aState.proto_segment.begin(); k != aState.proto_segment.end(); k++) {
662  const CSCRecHit2D* iRHk = *k;
663  CSCDetId idRHk = iRHk->cscDetId();
664  int kLayer = idRHk.layer();
665  if (kLayer < min_layer) {
666  min_layer = kLayer;
667  min = k;
668  }
669  }
670  buffer.push_back(*min);
671  aState.proto_segment.erase(min);
672  } //while
673 
674  aState.proto_segment.clear();
675  for (ChamberHitContainer::const_iterator cand = buffer.begin(); cand != buffer.end(); cand++) {
676  aState.proto_segment.push_back(*cand);
677  }
678 
679  for (ChamberHitContainer::const_iterator iRH = aState.proto_segment.begin(); iRH != aState.proto_segment.end();
680  iRH++) {
681  const CSCRecHit2D* iRHp = *iRH;
682  CSCDetId idRH = iRHp->cscDetId();
683  int kRing = idRH.ring();
684  int kStation = idRH.station();
685  int kLayer = idRH.layer();
686  // Find the strip containing this hit
687  int centerid = iRHp->nStrips() / 2;
688  int centerStrip = iRHp->channels(centerid);
689  float stpos = (*iRHp).positionWithinStrip();
690  se(kLayer - 1) = (*iRHp).errorWithinStrip();
691  // Take into account half-strip staggering of layers (ME1/1 has no staggering)
692  if (kStation == 1 && (kRing == 1 || kRing == 4))
693  sp(kLayer - 1) = stpos + centerStrip;
694  else {
695  if (kLayer == 1 || kLayer == 3 || kLayer == 5)
696  sp(kLayer - 1) = stpos + centerStrip;
697  if (kLayer == 2 || kLayer == 4 || kLayer == 6)
698  sp(kLayer - 1) = stpos - 0.5 + centerStrip;
699  }
700  }
701  float chi2_str;
702  fitX(aState, sp, se, -1, -1, chi2_str);
703 
704  //-----------------------------------------------------
705  // Optimal point rejection method
706  //-----------------------------------------------------
707  float minSum = 1000;
708  int i1b = 0;
709  int i2b = 0;
710  int iworst = -1;
711  int bad_layer = -1;
712  ChamberHitContainer::const_iterator rh_to_be_deleted_1;
713  ChamberHitContainer::const_iterator rh_to_be_deleted_2;
714  if ((chi2_str) > aState.chi2_str_ * aState.chi2D_iadd) {
715  for (ChamberHitContainer::const_iterator i1 = aState.proto_segment.begin(); i1 != aState.proto_segment.end();
716  ++i1) {
717  ++i1b;
718  const CSCRecHit2D* i1_1 = *i1;
719  CSCDetId idRH1 = i1_1->cscDetId();
720  int z1 = idRH1.layer();
721  i2b = i1b;
722  for (ChamberHitContainer::const_iterator i2 = i1 + 1; i2 != aState.proto_segment.end(); ++i2) {
723  ++i2b;
724  const CSCRecHit2D* i2_1 = *i2;
725  CSCDetId idRH2 = i2_1->cscDetId();
726  int z2 = idRH2.layer();
727  int irej = 0;
728  for (ChamberHitContainer::const_iterator ir = aState.proto_segment.begin(); ir != aState.proto_segment.end();
729  ++ir) {
730  ++irej;
731  if (ir == i1 || ir == i2)
732  continue;
733  float dsum = 0;
734  int hit_nr = 0;
735  const CSCRecHit2D* ir_1 = *ir;
736  CSCDetId idRH = ir_1->cscDetId();
737  int worst_layer = idRH.layer();
738  for (ChamberHitContainer::const_iterator i = aState.proto_segment.begin(); i != aState.proto_segment.end();
739  ++i) {
740  ++hit_nr;
741  const CSCRecHit2D* i_1 = *i;
742  if (i == i1 || i == i2 || i == ir)
743  continue;
744  float slope = (sp(z2 - 1) - sp(z1 - 1)) / (z2 - z1);
745  float intersept = sp(z1 - 1) - slope * z1;
746  CSCDetId idRH = i_1->cscDetId();
747  int z = idRH.layer();
748  float di = fabs(sp(z - 1) - intersept - slope * z);
749  dsum = dsum + di;
750  } //i
751  if (dsum < minSum) {
752  minSum = dsum;
753  bad_layer = worst_layer;
754  iworst = irej;
755  rh_to_be_deleted_1 = ir;
756  }
757  } //ir
758  } //i2
759  } //i1
760  fitX(aState, sp, se, bad_layer, -1, chi2_str);
761  } //if chi2prob<1.0e-4
762 
763  //find worst from n-1 hits
764  int iworst2 = -1;
765  int bad_layer2 = -1;
766  if (iworst > -1 && (nhits - 1) > n_seg_min && (chi2_str) > aState.chi2_str_ * aState.chi2D_iadd) {
767  iworst = -1;
768  float minSum = 1000;
769  int i1b = 0;
770  int i2b = 0;
771  for (ChamberHitContainer::const_iterator i1 = aState.proto_segment.begin(); i1 != aState.proto_segment.end();
772  ++i1) {
773  ++i1b;
774  const CSCRecHit2D* i1_1 = *i1;
775  CSCDetId idRH1 = i1_1->cscDetId();
776  int z1 = idRH1.layer();
777  i2b = i1b;
778  for (ChamberHitContainer::const_iterator i2 = i1 + 1; i2 != aState.proto_segment.end(); ++i2) {
779  ++i2b;
780  const CSCRecHit2D* i2_1 = *i2;
781  CSCDetId idRH2 = i2_1->cscDetId();
782  int z2 = idRH2.layer();
783  int irej = 0;
784  for (ChamberHitContainer::const_iterator ir = aState.proto_segment.begin(); ir != aState.proto_segment.end();
785  ++ir) {
786  ++irej;
787  int irej2 = 0;
788  if (ir == i1 || ir == i2)
789  continue;
790  const CSCRecHit2D* ir_1 = *ir;
791  CSCDetId idRH = ir_1->cscDetId();
792  int worst_layer = idRH.layer();
793  for (ChamberHitContainer::const_iterator ir2 = aState.proto_segment.begin();
794  ir2 != aState.proto_segment.end();
795  ++ir2) {
796  ++irej2;
797  if (ir2 == i1 || ir2 == i2 || ir2 == ir)
798  continue;
799  float dsum = 0;
800  int hit_nr = 0;
801  const CSCRecHit2D* ir2_1 = *ir2;
802  CSCDetId idRH = ir2_1->cscDetId();
803  int worst_layer2 = idRH.layer();
804  for (ChamberHitContainer::const_iterator i = aState.proto_segment.begin(); i != aState.proto_segment.end();
805  ++i) {
806  ++hit_nr;
807  const CSCRecHit2D* i_1 = *i;
808  if (i == i1 || i == i2 || i == ir || i == ir2)
809  continue;
810  float slope = (sp(z2 - 1) - sp(z1 - 1)) / (z2 - z1);
811  float intersept = sp(z1 - 1) - slope * z1;
812  CSCDetId idRH = i_1->cscDetId();
813  int z = idRH.layer();
814  float di = fabs(sp(z - 1) - intersept - slope * z);
815  dsum = dsum + di;
816  } //i
817  if (dsum < minSum) {
818  minSum = dsum;
819  iworst2 = irej2;
820  iworst = irej;
821  bad_layer = worst_layer;
822  bad_layer2 = worst_layer2;
823  rh_to_be_deleted_1 = ir;
824  rh_to_be_deleted_2 = ir2;
825  }
826  } //ir2
827  } //ir
828  } //i2
829  } //i1
830  fitX(aState, sp, se, bad_layer, bad_layer2, chi2_str);
831  } //if prob(n-1)<e-4
832 
833  //----------------------------------
834  //erase bad_hits
835  //----------------------------------
836  if (iworst2 - 1 >= 0 && iworst2 <= int(aState.proto_segment.size())) {
837  aState.proto_segment.erase(rh_to_be_deleted_2);
838  }
839  if (iworst - 1 >= 0 && iworst <= int(aState.proto_segment.size())) {
840  aState.proto_segment.erase(rh_to_be_deleted_1);
841  }
842 }
843 
845  const AlgoState& aState, SVector6 points, SVector6 errors, int ir, int ir2, float& chi2_str) const {
846  float S = 0;
847  float Sx = 0;
848  float Sy = 0;
849  float Sxx = 0;
850  float Sxy = 0;
851  float sigma2 = 0;
852  for (int i = 1; i < 7; i++) {
853  if (i == ir || i == ir2 || points(i - 1) == 0.)
854  continue;
855  sigma2 = errors(i - 1) * errors(i - 1);
856  float i1 = i - 3.5;
857  S = S + (1 / sigma2);
858  Sy = Sy + (points(i - 1) / sigma2);
859  Sx = Sx + ((i1) / sigma2);
860  Sxx = Sxx + (i1 * i1) / sigma2;
861  Sxy = Sxy + (((i1)*points(i - 1)) / sigma2);
862  }
863  float delta = S * Sxx - Sx * Sx;
864  float intercept = (Sxx * Sy - Sx * Sxy) / delta;
865  float slope = (S * Sxy - Sx * Sy) / delta;
866  float chi_str = 0;
867  chi2_str = 0;
868  // calculate chi2_str
869  for (int i = 1; i < 7; i++) {
870  if (i == ir || i == ir2 || points(i - 1) == 0.)
871  continue;
872  chi_str = (points(i - 1) - intercept - slope * (i - 3.5)) / (errors(i - 1));
873  chi2_str = chi2_str + chi_str * chi_str;
874  }
875  return (intercept + slope * 0);
876 }
877 
878 bool CSCSegAlgoRU::hasHitOnLayer(const AlgoState& aState, int layer) const {
879  // Is there is already a hit on this layer?
881  for (it = aState.proto_segment.begin(); it != aState.proto_segment.end(); it++)
882  if ((*it)->cscDetId().layer() == layer)
883  return true;
884  return false;
885 }
886 
887 bool CSCSegAlgoRU::replaceHit(AlgoState& aState, const CSCRecHit2D* h, int layer) const {
888  // replace a hit from a layer
889  ChamberHitContainer::const_iterator it;
890  for (it = aState.proto_segment.begin(); it != aState.proto_segment.end();) {
891  if ((*it)->cscDetId().layer() == layer)
892  it = aState.proto_segment.erase(it);
893  else
894  ++it;
895  }
896  return addHit(aState, h, layer);
897 }
898 
899 void CSCSegAlgoRU::compareProtoSegment(AlgoState& aState, const CSCRecHit2D* h, int layer) const {
900  // Copy the input CSCSegFit
901  std::unique_ptr<CSCSegFit> oldfit;
902  oldfit = std::make_unique<CSCSegFit>(aState.aChamber, aState.proto_segment);
903  oldfit->fit();
904  ChamberHitContainer oldproto = aState.proto_segment;
905 
906  // May create a new fit
907  bool ok = replaceHit(aState, h, layer);
908  if ((aState.sfit->chi2() >= oldfit->chi2()) || !ok) {
909  // keep original fit
910  aState.proto_segment = oldproto;
911  aState.sfit = std::move(oldfit); // reset to the original input fit
912  }
913 }
914 
915 void CSCSegAlgoRU::increaseProtoSegment(AlgoState& aState, const CSCRecHit2D* h, int layer, int chi2_factor) const {
916  // Creates a new fit
917  std::unique_ptr<CSCSegFit> oldfit;
918  ChamberHitContainer oldproto = aState.proto_segment;
919  oldfit = std::make_unique<CSCSegFit>(aState.aChamber, aState.proto_segment);
920  oldfit->fit();
921 
922  bool ok = addHit(aState, h, layer);
923  //@@ TEST ON ndof<=0 IS JUST TO ACCEPT nhits=2 CASE??
924  if (!ok || ((aState.sfit->ndof() > 0) && (aState.sfit->chi2() / aState.sfit->ndof() >= aState.chi2Max))) {
925  // reset to original fit
926  aState.proto_segment = oldproto;
927  aState.sfit = std::move(oldfit);
928  }
929 }
Vector3DBase
Definition: Vector3DBase.h:8
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The position (origin of the R.F.)
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Return the layer corresponding to the given id.
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Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
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Definition: PV3DBase.h:60
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Definition: CSCSegAlgoRU.cc:594
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Definition: CSCSegAlgoRU.h:165
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Definition: cmsLHEtoEOSManager.py:204
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Definition: CSCSegAlgoRU.cc:577
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Definition: EPCuts.h:4
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Definition: CSCSegAlgoRU.cc:444
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Extracting strip channel numbers comprising the rechit - low.
Definition: CSCRecHit2D.h:61
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Utility functions.
Definition: CSCSegAlgoRU.cc:608
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Definition: CSCSegAlgoRU.cc:57
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Definition: CSCSegAlgoRU.h:48
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Definition: CSCSegAlgoRU.h:155
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Definition: CSCDetId.h:79
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Definition: CSCRecHit2D.h:62
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Definition: CSCRecHit2D.h:68
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Definition: dqmiolumiharvest.py:66
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Definition: CastorTimeSlew.cc:6
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Definition: CSCSegAlgoRU.cc:562
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Definition: DTTMax.h:29
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Definition: PV3DBase.h:69
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Definition: CSCSegAlgoRU.cc:472
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Definition: CSCSegAlgoRU.cc:629
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Utility functions.
Definition: CSCSegAlgoRU.cc:397
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static const std::string kLayer("layer")
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Definition: CSCSegAlgoRU.cc:899
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Definition: CSCSegAlgoRU.h:160
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Definition: CSCSegAlgoRU.h:162
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Definition: debug_messages_cfi.py:54