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TkLasBeamFitter.cc
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1 
17 // framework include files
29 
35 
36 // data formats
37 // for edm::InRun
39 
40 // laser data formats
43 
44 // further includes
49 
50 #include <iostream>
51 #include "TMinuit.h"
52 #include "TGraphErrors.h"
53 #include "TF1.h"
54 #include "TH1.h"
55 #include "TH2.h"
56 
57 using namespace edm;
58 using namespace std;
59 
60 
61 //
62 // class declaration
63 //
64 
65 class TkLasBeamFitter : public edm::one::EDProducer<edm::EndRunProducer> {
66 public:
67  explicit TkLasBeamFitter(const edm::ParameterSet &config);
68  ~TkLasBeamFitter();
69 
70  //virtual void beginJob(const edm::EventSetup& /*access deprecated*/) {}
71  virtual void produce(edm::Event &event, const edm::EventSetup &setup) override;
72  // virtual void beginRun(edm::Run &run, const edm::EventSetup &setup);
73  virtual void endRunProduce(edm::Run &run, const edm::EventSetup &setup) override;
74  //virtual void endJob() {}
75 
76 private:
79  void getLasBeams(TkFittedLasBeam &beam,vector<TrajectoryStateOnSurface> &tsosLas);
80  void getLasHits(TkFittedLasBeam &beam, const SiStripLaserRecHit2D &hit,
81  vector<const GeomDetUnit*> &gd, vector<GlobalPoint> &globHit,
82  unsigned int &hitsAtTecPlus);
83 // void fillVectors(TkFittedLasBeam &beam);
84 
85  // need static functions to be used in fitter(..);
86  // all parameters used therein have to be static, as well (see below)
87  static double tecPlusFunction(double *x, double *par);
88  static double tecMinusFunction(double *x, double *par);
89  static double atFunction(double *x, double *par);
90 
91  void fitter(TkFittedLasBeam &beam, AlgebraicSymMatrix &covMatrix,
92  unsigned int &hitsAtTecPlus, unsigned int &nFitParams,
93  std::vector<double> &hitPhi, std::vector<double> &hitPhiError, std::vector<double> &hitZprimeError,
94  double &zMin, double &zMax, double &bsAngleParam,
95  double &offset, double &offsetError, double &slope, double &slopeError,
96  double &phiAtMinusParam, double &phiAtPlusParam,
97  double &atThetaSplitParam);
98 
99  void trackPhi(TkFittedLasBeam &beam, unsigned int &hit,
100  double &trackPhi, double &trackPhiRef,
101  double &offset, double &slope, double &bsAngleParam,
102  double &phiAtMinusParam, double &phiAtPlusParam,
103  double &atThetaSplitParam, std::vector<GlobalPoint> &globHit);
104 
105  void globalTrackPoint(TkFittedLasBeam &beam,
106  unsigned int &hit, unsigned int &hitsAtTecPlus,
107  double &trackPhi, double &trackPhiRef,
108  std::vector<GlobalPoint> &globHit, std::vector<GlobalPoint> &globPtrack,
109  GlobalPoint &globPref, std::vector<double> &hitPhiError);
110 
111  void buildTrajectory(TkFittedLasBeam &beam, unsigned int &hit,
112  vector<const GeomDetUnit*> &gd, std::vector<GlobalPoint> &globPtrack,
113  vector<TrajectoryStateOnSurface> &tsosLas, GlobalPoint &globPref);
114 
115  bool fitBeam(TkFittedLasBeam &beam, AlgebraicSymMatrix &covMatrix,
116  unsigned int &hitsAtTecPlus, unsigned int &nFitParams,
117  double &offset, double &slope, vector<GlobalPoint> &globPtrack,
118  double &bsAngleParam, double &chi2);
119 
120  // ----------member data ---------------------------
123  unsigned int nAtParameters_;
124 
126 
127  // static parameters used in static parametrization functions
128  static vector<double> gHitZprime;
129  static vector<double> gBarrelModuleRadius;
130  static vector<double> gBarrelModuleOffset;
131  static float gTIBparam;
132  static float gTOBparam;
133  static double gBeamR;
134  static double gBeamZ0;
135  static double gBeamSplitterZprime;
136  static unsigned int gHitsAtTecMinus;
137  static double gBSparam;
138  static bool gFitBeamSplitters;
139  static bool gIsInnerBarrel;
140 
141  // histograms
142  TH1F *h_bsAngle, *h_hitX, *h_hitXTecPlus, *h_hitXTecMinus,
143  *h_hitXAt, *h_chi2, *h_chi2ndof, *h_pull, *h_res,
144  *h_resTecPlus, *h_resTecMinus, *h_resAt;
145  TH2F *h_bsAngleVsBeam, *h_hitXvsZTecPlus, *h_hitXvsZTecMinus,
146  *h_hitXvsZAt, *h_resVsZTecPlus, *h_resVsZTecMinus, *h_resVsZAt,
147  *h_resVsHitTecPlus, *h_resVsHitTecMinus, *h_resVsHitAt;
148 };
149 
150 //
151 // constants, enums and typedefs
152 //
153 
154 
155 //
156 // static data member definitions
157 //
158 
159 // static parameters used in parametrization functions
160 vector<double> TkLasBeamFitter::gHitZprime;
163 float TkLasBeamFitter::gTIBparam = 0.097614; // = abs(r_offset/r_module) (nominal!)
164 float TkLasBeamFitter::gTOBparam = 0.034949; // = abs(r_offset/r_module) (nominal!)
165 double TkLasBeamFitter::gBeamR = 0.0;
166 double TkLasBeamFitter::gBeamZ0 = 0.0;
168 unsigned int TkLasBeamFitter::gHitsAtTecMinus = 0;
169 double TkLasBeamFitter::gBSparam = 0.0;
172 
173 // handles
177 
178 //
179 // constructors and destructor
180 //
182  src_(iConfig.getParameter<edm::InputTag>("src")),
183  fitBeamSplitters_(iConfig.getParameter<bool>("fitBeamSplitters")),
184  nAtParameters_(iConfig.getParameter<unsigned int>("numberOfFittedAtParameters")),
185  h_bsAngle(0), h_hitX(0), h_hitXTecPlus(0), h_hitXTecMinus(0),
186  h_hitXAt(0), h_chi2(0), h_chi2ndof(0), h_pull(0), h_res(0),
187  h_resTecPlus(0), h_resTecMinus(0), h_resAt(0),
188  h_bsAngleVsBeam(0), h_hitXvsZTecPlus(0), h_hitXvsZTecMinus(0),
189  h_hitXvsZAt(0), h_resVsZTecPlus(0), h_resVsZTecMinus(0), h_resVsZAt(0),
190  h_resVsHitTecPlus(0), h_resVsHitTecMinus(0), h_resVsHitAt(0)
191 {
192  // declare the products to produce
193  this->produces<TkFittedLasBeamCollection, edm::Transition::EndRun>();
194  this->produces<TsosVectorCollection, edm::Transition::EndRun>();
195 
196  //now do what ever other initialization is needed
197 }
198 
199 //---------------------------------------------------------------------------------------
201 {
202 
203  // do anything here that needs to be done at desctruction time
204  // (e.g. close files, deallocate resources etc.)
205 
206 }
207 
208 
209 //
210 // member functions
211 //
212 
213 //---------------------------------------------------------------------------------------
214 // ------------ method called to produce the data ------------
216 {
217  // Nothing per event!
218 }
219 
220 //---------------------------------------------------------------------------------------
221 // ------------ method called at end of each run ---------------------------------------
223 {
224 // }
225 // // FIXME!
226 // // Indeed, that should be in endRun(..) - as soon as AlignmentProducer can call
227 // // the algorithm's endRun correctly!
228 //
229 //
230 // void TkLasBeamFitter::beginRun(edm::Run &run, const edm::EventSetup &setup)
231 // {
232 
233  // book histograms
234  h_hitX = fs->make<TH1F>("hitX","local x of LAS hits;local x [cm];N",100,-0.5,0.5);
235  h_hitXTecPlus = fs->make<TH1F>("hitXTecPlus","local x of LAS hits in TECplus;local x [cm];N",100,-0.5,0.5);
236  h_hitXTecMinus = fs->make<TH1F>("hitXTecMinus","local x of LAS hits in TECminus;local x [cm];N",100,-0.5,0.5);
237  h_hitXAt = fs->make<TH1F>("hitXAt","local x of LAS hits in ATs;local x [cm];N",100,-2.5,2.5);
238  h_hitXvsZTecPlus = fs->make<TH2F>("hitXvsZTecPlus","local x vs z in TECplus;z [cm];local x [cm]",80,120,280,100,-0.5,0.5);
239  h_hitXvsZTecMinus = fs->make<TH2F>("hitXvsZTecMinus","local x vs z in TECMinus;z [cm];local x [cm]",80,-280,-120,100,-0.5,0.5);
240  h_hitXvsZAt = fs->make<TH2F>("hitXvsZAt","local x vs z in ATs;z [cm];local x [cm]",200,-200,200,100,-0.5,0.5);
241  h_chi2 = fs->make<TH1F>("chi2","#chi^{2};#chi^{2};N",100,0,2000);
242  h_chi2ndof = fs->make<TH1F>("chi2ndof","#chi^{2} per degree of freedom;#chi^{2}/N_{dof};N",100,0,300);
243  h_pull = fs->make<TH1F>("pull","pulls of #phi residuals;pull;N",50,-10,10);
244  h_res = fs->make<TH1F>("res","#phi residuals;#phi_{track} - #phi_{hit} [rad];N",60,-0.0015,0.0015);
245  h_resTecPlus = fs->make<TH1F>("resTecPlus","#phi residuals in TECplus;#phi_{track} - #phi_{hit} [rad];N",30,-0.0015,0.0015);
246  h_resTecMinus = fs->make<TH1F>("resTecMinus","#phi residuals in TECminus;#phi_{track} - #phi_{hit} [rad];N",60,-0.0015,0.0015);
247  h_resAt = fs->make<TH1F>("resAt","#phi residuals in ATs;#phi_{track} - #phi_{hit} [rad];N",30,-0.0015,0.0015);
248  h_resVsZTecPlus = fs->make<TH2F>("resVsZTecPlus","phi residuals vs. z in TECplus;z [cm];#phi_{track} - #phi_{hit} [rad]",
249  80,120,280,100,-0.0015,0.0015);
250  h_resVsZTecMinus = fs->make<TH2F>("resVsZTecMinus","phi residuals vs. z in TECminus;z [cm];#phi_{track} - #phi_{hit} [rad]",
251  80,-280,-120,100,-0.0015,0.0015);
252  h_resVsZAt = fs->make<TH2F>("resVsZAt","#phi residuals vs. z in ATs;N;#phi_{track} - #phi_{hit} [rad]",
253  200,-200,200,100,-0.0015,0.0015);
254  h_resVsHitTecPlus = fs->make<TH2F>("resVsHitTecPlus","#phi residuals vs. hits in TECplus;hit no.;#phi_{track} - #phi_{hit} [rad]",
255  144,0,144,100,-0.0015,0.0015);
256  h_resVsHitTecMinus = fs->make<TH2F>("resVsHitTecMinus","#phi residuals vs. hits in TECminus;hit no.;#phi_{track} - #phi_{hit} [rad]",
257  144,0,144,100,-0.0015,0.0015);
258  h_resVsHitAt = fs->make<TH2F>("resVsHitAt","#phi residuals vs. hits in ATs;hit no.;#phi_{track} - #phi_{hit} [rad]",
259  176,0,176,100,-0.0015,0.0015);
260  h_bsAngle = fs->make<TH1F>("bsAngle","fitted beam splitter angle;BS angle [rad];N",40,-0.004,0.004);
261  h_bsAngleVsBeam = fs->make<TH2F>("bsAngleVsBeam","fitted beam splitter angle per beam;Beam no.;BS angle [rad]",
262  40,0,300,100,-0.004,0.004);
263 
264  // Create output collections - they are parallel.
265  // (edm::Ref etc. and thus edm::AssociationVector are not supported for edm::Run...)
266  auto fittedBeams = std::make_unique<TkFittedLasBeamCollection>();
267  // One std::vector<TSOS> for each TkFittedLasBeam:
268  auto tsosesVec = std::make_unique<TsosVectorCollection>();
269 
270  // get TkLasBeams, Tracker geometry, magnetic field
271  run.getByLabel( "LaserAlignment", "tkLaserBeams", laserBeams );
272  setup.get<TrackerDigiGeometryRecord>().get(geometry);
273  setup.get<IdealMagneticFieldRecord>().get(fieldHandle);
274 
275  // hack for fixed BSparams (ugly!)
276 // double bsParams[34] = {-0.000266,-0.000956,-0.001205,-0.000018,-0.000759,0.002554,
277 // 0.000465,0.000975,0.001006,0.002027,-0.001263,-0.000763,
278 // -0.001702,0.000906,-0.002120,0.001594,0.000661,-0.000457,
279 // -0.000447,0.000347,-0.002266,-0.000446,0.000659,0.000018,
280 // -0.001630,-0.000324,
281 // // ATs
282 // -999.,-0.001709,-0.002091,-999.,
283 // -0.001640,-999.,-0.002444,-0.002345};
284 
285  double bsParams[40] = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,
286  0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
287 
288  // beam counter
289  unsigned int beamNo(0);
290  // fit BS? If false, values from bsParams are taken
292  if(fitBeamSplitters_) cout << "Fitting BS!" << endl;
293  else cout << "BS fixed, not fitted!" << endl;
294 
295  // loop over LAS beams
296  for(TkLasBeamCollection::const_iterator iBeam = laserBeams->begin(), iEnd = laserBeams->end();
297  iBeam != iEnd; ++iBeam){
298 
299  TkFittedLasBeam beam(*iBeam);
300  vector<TrajectoryStateOnSurface> tsosLas;
301 
302  // set BS param for fit
303  gBSparam = bsParams[beamNo];
304 
305  // call main function; all other functions are called inside getLasBeams(..)
306  this->getLasBeams(beam, tsosLas);
307 
308  // fill output products
309  fittedBeams->push_back(beam);
310  tsosesVec->push_back(tsosLas);
311 
312 // if(!this->fitBeam(fittedBeams->back(), tsosesVec->back())){
313 // edm::LogError("BadFit")
314 // << "Problems fitting TkLasBeam, id " << fittedBeams->back().getBeamId() << ".";
315 // fittedBeams->pop_back(); // remove last entry added just before
316 // tsosesVec->pop_back(); // dito
317 // }
318 
319  beamNo++;
320  }
321 
322  // finally, put fitted beams and TSOS vectors into run
323  run.put(std::move(fittedBeams));
324  run.put(std::move(tsosesVec));
325 }
326 
327 // methods for las data processing
328 
329 // -------------- loop over beams, call functions ----------------------------
330 void TkLasBeamFitter::getLasBeams(TkFittedLasBeam &beam, vector<TrajectoryStateOnSurface> &tsosLas)
331 {
332  cout << "---------------------------------------" << endl;
333  cout << "beam id: " << beam.getBeamId() // << " isTec: " << (beam.isTecInternal() ? "Y" : "N")
334  << " isTec+: " << (beam.isTecInternal(1) ? "Y" : "N") << " isTec-: " << (beam.isTecInternal(-1) ? "Y" : "N")
335  << " isAt: " << (beam.isAlignmentTube() ? "Y" : "N") << " isR6: " << (beam.isRing6() ? "Y" : "N")
336  << endl;
337 
338  // reset static variables
339  gHitsAtTecMinus = 0;
340  gHitZprime.clear();
341  gBarrelModuleRadius.clear();
342  gBarrelModuleOffset.clear();
343 
344  // set right beam radius
345  gBeamR = beam.isRing6() ? 84.0 : 56.4;
346 
347  vector<const GeomDetUnit*> gd;
348  vector<GlobalPoint> globHit;
349  unsigned int hitsAtTecPlus(0);
350  double sumZ(0.);
351 
352  // loop over hits
353  for( TkLasBeam::const_iterator iHit = beam.begin(); iHit < beam.end(); ++iHit ){
354  // iHit is a SiStripLaserRecHit2D
355 
356  const SiStripLaserRecHit2D hit(*iHit);
357 
358  this->getLasHits(beam, hit, gd, globHit, hitsAtTecPlus);
359  sumZ += globHit.back().z();
360 
361  // fill histos
362  h_hitX->Fill(hit.localPosition().x());
363  // TECplus
364  if(beam.isTecInternal(1)){
365  h_hitXTecPlus->Fill(hit.localPosition().x());
366  h_hitXvsZTecPlus->Fill(globHit.back().z(),hit.localPosition().x());
367  }
368  // TECminus
369  else if(beam.isTecInternal(-1)){
370  h_hitXTecMinus->Fill(hit.localPosition().x());
371  h_hitXvsZTecMinus->Fill(globHit.back().z(),hit.localPosition().x());
372  }
373  // ATs
374  else{
375  h_hitXAt->Fill(hit.localPosition().x());
376  h_hitXvsZAt->Fill(globHit.back().z(),hit.localPosition().x());
377  }
378  }
379 
380  gBeamZ0 = sumZ / globHit.size();
381  double zMin(0.), zMax(0.);
382  // TECplus
383  if(beam.isTecInternal(1)){
384  gBeamSplitterZprime = 205.75 - gBeamZ0;
385  zMin = 120.0 - gBeamZ0;
386  zMax = 280.0 - gBeamZ0;
387  }
388  // TECminus
389  else if(beam.isTecInternal(-1)){
390  gBeamSplitterZprime = -205.75 - gBeamZ0;
391  zMin = -280.0 - gBeamZ0;
392  zMax = -120.0 - gBeamZ0;
393  }
394  // AT
395  else{
396  gBeamSplitterZprime = 112.3 - gBeamZ0;
397  zMin = -200.0 - gBeamZ0;
398  zMax = 200.0 - gBeamZ0;
399  }
400 
401  // fill vectors for fitted quantities
402  vector<double> hitPhi, hitPhiError, hitZprimeError;
403 
404  for(unsigned int hit = 0; hit < globHit.size(); ++hit){
405  hitPhi.push_back(static_cast<double>(globHit[hit].phi()));
406  // localPositionError[hit] or assume 0.003, 0.006
407  hitPhiError.push_back( 0.003 / globHit[hit].perp());
408  // no errors on z, fill with zeros
409  hitZprimeError.push_back(0.0);
410  // barrel-specific values
411  if(beam.isAlignmentTube() && abs(globHit[hit].z()) < 112.3){
412  gBarrelModuleRadius.push_back(globHit[hit].perp());
413  gBarrelModuleOffset.push_back(gBarrelModuleRadius.back() - gBeamR);
414  // TIB/TOB flag
415  if(gBarrelModuleOffset.back() < 0.0){
416  gIsInnerBarrel = 1;
417  }
418  else{
419  gIsInnerBarrel = 0;
420  }
421  gHitZprime.push_back(globHit[hit].z() - gBeamZ0 - abs(gBarrelModuleOffset.back()));
422  }
423  // non-barrel z'
424  else{
425  gHitZprime.push_back(globHit[hit].z() - gBeamZ0);
426  }
427  }
428 
429  // number of fit parameters, 3 for TECs (always!); 3, 5, or 6 for ATs
430  unsigned int tecParams(3), atParams(0);
431  if(nAtParameters_ == 3) atParams = 3;
432  else if(nAtParameters_ == 5) atParams = 5;
433  else atParams = 6; // <-- default value, recommended
434  unsigned int nFitParams(0);
435  if(!fitBeamSplitters_ ||
436  (hitsAtTecPlus == 0 && beam.isAlignmentTube() ) ){
437  tecParams = tecParams - 1;
438  atParams = atParams - 1;
439  }
440  if(beam.isTecInternal()){
441  nFitParams = tecParams;
442  }
443  else{
444  nFitParams = atParams;
445  }
446 
447  // fit parameter definitions
448  double offset(0.), offsetError(0.), slope(0.), slopeError(0.),
449  bsAngleParam(0.), phiAtMinusParam(0.), phiAtPlusParam(0.),
450  atThetaSplitParam(0.);
451  AlgebraicSymMatrix covMatrix;
452  if(!fitBeamSplitters_ || (beam.isAlignmentTube() && hitsAtTecPlus == 0)){
453  covMatrix = AlgebraicSymMatrix(nFitParams, 1);
454  }
455  else{
456  covMatrix = AlgebraicSymMatrix(nFitParams - 1, 1);
457  }
458 
459  this->fitter(beam, covMatrix,
460  hitsAtTecPlus, nFitParams,
461  hitPhi, hitPhiError, hitZprimeError,
462  zMin, zMax, bsAngleParam,
463  offset, offsetError, slope, slopeError,
464  phiAtMinusParam, phiAtPlusParam,
465  atThetaSplitParam);
466 
467  vector<GlobalPoint> globPtrack;
468  GlobalPoint globPref;
469  double chi2(0.);
470 
471  for(unsigned int hit = 0; hit < gHitZprime.size(); ++hit){
472 
473  // additional phi value (trackPhiRef) for trajectory calculation
474  double trackPhi(0.), trackPhiRef(0.);
475 
476  this->trackPhi(beam, hit, trackPhi, trackPhiRef,
477  offset, slope, bsAngleParam,
478  phiAtMinusParam, phiAtPlusParam,
479  atThetaSplitParam, globHit);
480 
481  cout << "track phi = " << trackPhi
482  << ", hit phi = " << hitPhi[hit]
483  << ", zPrime = " << gHitZprime[hit]
484  << " r = " << globHit[hit].perp() << endl;
485 
486  this->globalTrackPoint(beam, hit, hitsAtTecPlus,
487  trackPhi, trackPhiRef,
488  globHit, globPtrack, globPref,
489  hitPhiError);
490 
491  // calculate residuals = pred - hit (in global phi)
492  const double phiResidual = globPtrack[hit].phi() - globHit[hit].phi();
493  // pull calculation (FIX!!!)
494  const double phiResidualPull = phiResidual / hitPhiError[hit];
495  // sqrt(hitPhiError[hit]*hitPhiError[hit] +
496  // (offsetError*offsetError + globPtrack[hit].z()*globPtrack[hit].z() * slopeError*slopeError));
497 
498  // calculate chi2
499  chi2 += phiResidual*phiResidual / (hitPhiError[hit]*hitPhiError[hit]);
500 
501  // fill histos
502  h_res->Fill(phiResidual);
503  // TECplus
504  if(beam.isTecInternal(1)){
505  h_pull->Fill(phiResidualPull);
506  h_resTecPlus->Fill(phiResidual);
507  h_resVsZTecPlus->Fill(globPtrack[hit].z(), phiResidual);
508  // Ring 6
509  if(beam.isRing6()){
510  h_resVsHitTecPlus->Fill(hit+(beam.getBeamId()-1)/10*9+72, phiResidual);
511  }
512  // Ring 4
513  else{
514  h_resVsHitTecPlus->Fill(hit+beam.getBeamId()/10*9, phiResidual);
515  }
516  }
517  // TECminus
518  else if(beam.isTecInternal(-1)){
519  h_pull->Fill(phiResidualPull);
520  h_resTecMinus->Fill(phiResidual);
521  h_resVsZTecMinus->Fill(globPtrack[hit].z(), phiResidual);
522  // Ring 6
523  if(beam.isRing6()){
524  h_resVsHitTecMinus->Fill(hit+(beam.getBeamId()-101)/10*9+72, phiResidual);
525  }
526  // Ring 4
527  else{
528  h_resVsHitTecMinus->Fill(hit+(beam.getBeamId()-100)/10*9, phiResidual);
529  }
530  }
531  // ATs
532  else{
533  h_pull->Fill(phiResidualPull);
534  h_resAt->Fill(phiResidual);
535  h_resVsZAt->Fill(globPtrack[hit].z(), phiResidual);
536  h_resVsHitAt->Fill(hit+(beam.getBeamId()-200)/10*22, phiResidual);
537  }
538 
539  this->buildTrajectory(beam, hit, gd, globPtrack, tsosLas, globPref);
540  }
541 
542  cout << "chi^2 = " << chi2 << ", chi^2/ndof = " << chi2/(gHitZprime.size() - nFitParams) << endl;
543  this->fitBeam(beam, covMatrix, hitsAtTecPlus, nFitParams,
544  offset, slope, globPtrack, bsAngleParam, chi2);
545 
546  cout << "bsAngleParam = " << bsAngleParam << endl;
547 
548  // fill histos
549  // include slope, offset, covariance plots here
550  h_chi2->Fill(chi2);
551  h_chi2ndof->Fill(chi2/(gHitZprime.size() - nFitParams));
552  if(bsAngleParam != 0.0){
553  h_bsAngle->Fill(2.0*atan(0.5*bsAngleParam));
554  h_bsAngleVsBeam->Fill(beam.getBeamId(), 2.0*atan(0.5*bsAngleParam));
555  }
556 }
557 
558 
559 // --------- get hits, convert to global coordinates ---------------------------
561  vector<const GeomDetUnit*> &gd, vector<GlobalPoint> &globHit,
562  unsigned int &hitsAtTecPlus)
563 {
564  // get global position of LAS hits
565  gd.push_back(geometry->idToDetUnit(hit.getDetId()));
566  GlobalPoint globPtemp(gd.back()->toGlobal(hit.localPosition()));
567 
568  // testing: globPtemp should be right
569  globHit.push_back(globPtemp);
570 
571  if(beam.isAlignmentTube()){
572  if(abs(globPtemp.z()) > 112.3){
573  if(globPtemp.z() < 112.3) gHitsAtTecMinus++ ;
574  else hitsAtTecPlus++ ;
575  }
576  }
577 }
578 
579 
580 // ------------ parametrization functions for las beam fits ------------
581 double TkLasBeamFitter::tecPlusFunction(double *x, double *par)
582 {
583  double z = x[0]; // 'primed'? -> yes!!!
584 
585  if(z < gBeamSplitterZprime){
586  return par[0] + par[1] * z;
587  }
588  else{
589  if(gFitBeamSplitters){
590  // par[2] = 2*tan(BeamSplitterAngle/2.0)
591  return par[0] + par[1] * z - par[2] * (z - gBeamSplitterZprime)/gBeamR;
592  }
593  else{
594  return par[0] + par[1] * z - gBSparam * (z - gBeamSplitterZprime)/gBeamR;
595  }
596  }
597 }
598 
599 
600 double TkLasBeamFitter::tecMinusFunction(double *x, double *par)
601 {
602  double z = x[0]; // 'primed'? -> yes!!!
603 
604  if(z > gBeamSplitterZprime){
605  return par[0] + par[1] * z;
606  }
607  else{
608  if(gFitBeamSplitters){
609  // par[2] = 2*tan(BeamSplitterAngle/2.0)
610  return par[0] + par[1] * z + par[2] * (z - gBeamSplitterZprime)/gBeamR;
611  }
612  else{
613  return par[0] + par[1] * z + gBSparam * (z - gBeamSplitterZprime)/gBeamR;
614  }
615  }
616 }
617 
618 double TkLasBeamFitter::atFunction(double *x, double *par)
619 {
620  double z = x[0]; // 'primed'? -> yes!!!
621  // TECminus
622  if(z < -gBeamSplitterZprime - 2.0*gBeamZ0){
623  return par[0] + par[1] * z;
624  }
625  // BarrelMinus
626  else if(-gBeamSplitterZprime - 2.0*gBeamZ0 < z && z < -gBeamZ0){
627  // z value includes module offset from main beam axis
628  // TOB
629  if(!gIsInnerBarrel){
630  return par[0] + par[1] * z + gTOBparam * (par[2] + par[4]);
631  }
632  // TIB
633  else{
634  return par[0] + par[1] * z - gTIBparam * (par[2] - par[4]);
635  }
636  }
637  // BarrelPlus
638  else if(-gBeamZ0 < z && z < gBeamSplitterZprime){
639  // z value includes module offset from main beam axis
640  // TOB
641  if(!gIsInnerBarrel){
642  return par[0] + par[1] * z + gTOBparam * (par[3] - par[4]);
643  }
644  // TIB
645  else{
646  return par[0] + par[1] * z - gTIBparam * (par[3] + par[4]);
647  }
648  }
649  // TECplus
650  else{
651  if(gFitBeamSplitters){
652  // par[2] = 2*tan(BeamSplitterAngle/2.0)
653  return par[0] + par[1] * z - par[5] * (z - gBeamSplitterZprime)/gBeamR; // BS par: 5, 4, or 2
654  }
655  else{
656  return par[0] + par[1] * z - gBSparam * (z - gBeamSplitterZprime)/gBeamR;
657  }
658  }
659 }
660 
661 
662 // ------------ perform fit of beams ------------------------------------
664  unsigned int &hitsAtTecPlus, unsigned int &nFitParams,
665  vector<double> &hitPhi, vector<double> &hitPhiError, vector<double> &hitZprimeError,
666  double &zMin, double &zMax, double &bsAngleParam,
667  double &offset, double &offsetError, double &slope, double &slopeError,
668  double &phiAtMinusParam, double &phiAtPlusParam, double &atThetaSplitParam)
669 {
670  TGraphErrors *lasData = new TGraphErrors(gHitZprime.size(),
671  &(gHitZprime[0]), &(hitPhi[0]),
672  &(hitZprimeError[0]), &(hitPhiError[0]));
673 
674  // do fit (R = entire range)
675  if(beam.isTecInternal(1)){
676  TF1 tecPlus("tecPlus", tecPlusFunction, zMin, zMax, nFitParams );
677  tecPlus.SetParameter( 1, 0 ); // slope
678  tecPlus.SetParameter( nFitParams - 1, 0 ); // BS
679  lasData->Fit(&tecPlus, "R"); // "R", "RV" or "RQ"
680  }
681  else if(beam.isTecInternal(-1)){
682  TF1 tecMinus("tecMinus", tecMinusFunction, zMin, zMax, nFitParams );
683  tecMinus.SetParameter( 1, 0 ); // slope
684  tecMinus.SetParameter( nFitParams - 1, 0 ); // BS
685  lasData->Fit(&tecMinus, "R");
686  }
687  else{
688  TF1 at("at", atFunction, zMin, zMax, nFitParams );
689  at.SetParameter( 1, 0 ); // slope
690  at.SetParameter( nFitParams - 1, 0 ); // BS
691  lasData->Fit(&at,"R");
692  }
693 
694  // get values and errors for offset and slope
695  gMinuit->GetParameter(0, offset, offsetError);
696  gMinuit->GetParameter(1, slope, slopeError);
697 
698  // additional AT parameters
699  // define param errors that are not used later
700  double bsAngleParamError(0.), phiAtMinusParamError(0.),
701  phiAtPlusParamError(0.), atThetaSplitParamError(0.);
702 
703  if(beam.isAlignmentTube()){
704  gMinuit->GetParameter(2, phiAtMinusParam, phiAtMinusParamError);
705  gMinuit->GetParameter(3, phiAtPlusParam, phiAtPlusParamError);
706  gMinuit->GetParameter(4, atThetaSplitParam, atThetaSplitParamError);
707  }
708  // get Beam Splitter parameters
709  if(fitBeamSplitters_){
710  if(beam.isAlignmentTube() && hitsAtTecPlus == 0){
711  bsAngleParam = gBSparam;
712  }
713  else{
714  gMinuit->GetParameter( nFitParams - 1 , bsAngleParam, bsAngleParamError);
715  }
716  }
717  else{
718  bsAngleParam = gBSparam;
719  }
720 
721  // fill covariance matrix
722  vector<double> vec( covMatrix.num_col() * covMatrix.num_col() );
723  gMinuit->mnemat( &vec[0], covMatrix.num_col() );
724  for(int col = 0; col < covMatrix.num_col(); col++){
725  for(int row = 0; row < covMatrix.num_col(); row++){
726  covMatrix[col][row] = vec[row + covMatrix.num_col()*col];
727  }
728  }
729  // compute correlation between parameters
730 // double corr01 = covMatrix[1][0]/(offsetError*slopeError);
731 
732  delete lasData;
733 }
734 
735 
736 // -------------- calculate track phi value ----------------------------------
737 void TkLasBeamFitter::trackPhi(TkFittedLasBeam &beam, unsigned int &hit,
738  double &trackPhi, double &trackPhiRef,
739  double &offset, double &slope, double &bsAngleParam,
740  double &phiAtMinusParam, double &phiAtPlusParam,
741  double &atThetaSplitParam, vector<GlobalPoint> &globHit)
742 {
743  // TECplus
744  if(beam.isTecInternal(1)){
745  if(gHitZprime[hit] < gBeamSplitterZprime){
746  trackPhi = offset + slope * gHitZprime[hit];
747  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0);
748  }
749  else{
750  trackPhi = offset + slope * gHitZprime[hit]
751  - bsAngleParam * (gHitZprime[hit] - gBeamSplitterZprime)/gBeamR;
752  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0)
753  - bsAngleParam * ((gHitZprime[hit] + 1.0) - gBeamSplitterZprime)/gBeamR;
754  }
755  }
756  // TECminus
757  else if(beam.isTecInternal(-1)){
758  if(gHitZprime[hit] > gBeamSplitterZprime){
759  trackPhi = offset + slope * gHitZprime[hit];
760  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0);
761  }
762  else{
763  trackPhi = offset + slope * gHitZprime[hit]
764  + bsAngleParam * (gHitZprime[hit] - gBeamSplitterZprime)/gBeamR;
765  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0)
766  + bsAngleParam * ((gHitZprime[hit] + 1.0) - gBeamSplitterZprime)/gBeamR;
767  }
768  }
769  // ATs
770  else{
771  // TECminus
772  if(gHitZprime[hit] < -gBeamSplitterZprime - 2.0*gBeamZ0){
773  trackPhi = offset + slope * gHitZprime[hit];
774  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0);
775  }
776  // BarrelMinus
777  else if(-gBeamSplitterZprime - 2.0*gBeamZ0 < gHitZprime[hit] && gHitZprime[hit] < -gBeamZ0){
778  if(!gIsInnerBarrel){
779  trackPhi = offset + slope * gHitZprime[hit] + gTOBparam * (phiAtMinusParam + atThetaSplitParam);
780  }
781  else{
782  trackPhi = offset + slope * gHitZprime[hit] - gTIBparam * (phiAtMinusParam - atThetaSplitParam);
783  }
784  trackPhiRef = offset + slope * (gHitZprime[hit] + abs(gBarrelModuleOffset[hit-gHitsAtTecMinus]));
785  }
786  // BarrelPlus
787  else if(-gBeamZ0 < gHitZprime[hit] && gHitZprime[hit] < gBeamSplitterZprime){
788  if(!gIsInnerBarrel){
789  trackPhi = offset + slope * gHitZprime[hit] + gTOBparam * (phiAtPlusParam - atThetaSplitParam);
790  }
791  else{
792  trackPhi = offset + slope * gHitZprime[hit] - gTIBparam * (phiAtPlusParam + atThetaSplitParam);
793  }
794  trackPhiRef = offset + slope * (gHitZprime[hit] + abs(gBarrelModuleOffset[hit-gHitsAtTecMinus]));
795  }
796  // TECplus
797  else{
798  trackPhi = offset + slope * gHitZprime[hit]
799  - bsAngleParam * (gHitZprime[hit] - gBeamSplitterZprime)/gBeamR;
800  trackPhiRef = offset + slope * (gHitZprime[hit] + 1.0)
801  - bsAngleParam * ((gHitZprime[hit] + 1.0) - gBeamSplitterZprime)/gBeamR;
802  }
803  }
804 }
805 
806 
807 // -------------- calculate global track points, hit residuals, chi2 ----------------------------------
809  unsigned int &hit, unsigned int &hitsAtTecPlus,
810  double &trackPhi, double &trackPhiRef,
811  vector<GlobalPoint> &globHit, vector<GlobalPoint> &globPtrack,
812  GlobalPoint &globPref, vector<double> &hitPhiError)
813 {
814  // TECs
815  if(beam.isTecInternal(0)){
816  globPtrack.push_back(GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhi, globHit[hit].z())));
817  globPref = GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhiRef, globHit[hit].z() + 1.0));
818  }
819  // ATs
820  else{
821  // TECminus
822  if(hit < gHitsAtTecMinus){ // gHitZprime[hit] < -gBeamSplitterZprime - 2.0*gBeamZ0
823  globPtrack.push_back(GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhi, globHit[hit].z())));
824  globPref = GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhiRef, globHit[hit].z() + 1.0));
825  }
826  // TECplus
827  else if(hit > gHitZprime.size() - hitsAtTecPlus - 1){ // gHitZprime[hit] > gBeamSplitterZprime
828  globPtrack.push_back(GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhi, globHit[hit].z())));
829  globPref = GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhiRef, globHit[hit].z() + 1.0));
830  }
831  // Barrel
832  else{
833  globPtrack.push_back(GlobalPoint(GlobalPoint::Cylindrical(globHit[hit].perp(), trackPhi, globHit[hit].z())));
834  globPref = GlobalPoint(GlobalPoint::Cylindrical(gBeamR, trackPhiRef, globHit[hit].z()));
835  }
836  }
837 }
838 
839 
840 // ----------- create TrajectoryStateOnSurface for each track hit ----------------------------------------------
842  vector<const GeomDetUnit*> &gd, vector<GlobalPoint> &globPtrack,
843  vector<TrajectoryStateOnSurface> &tsosLas, GlobalPoint &globPref)
844 {
845  const MagneticField* magneticField = fieldHandle.product();
846  GlobalVector trajectoryState;
847 
848  // TECplus
849  if(beam.isTecInternal(1)){
850  trajectoryState = GlobalVector(globPref-globPtrack[hit]);
851  }
852  // TECminus
853  else if(beam.isTecInternal(-1)){
854  trajectoryState = GlobalVector(globPtrack[hit]-globPref);
855  }
856  // ATs
857  else{
858  // TECminus
859  if(gHitZprime[hit] < -gBeamSplitterZprime - 2.0*gBeamZ0){
860  trajectoryState = GlobalVector(globPtrack[hit]-globPref);
861  }
862  // TECplus
863  else if(gHitZprime[hit] > gBeamSplitterZprime){
864  trajectoryState = GlobalVector(globPref-globPtrack[hit]);
865  }
866  // Barrel
867  else{
868  trajectoryState = GlobalVector(globPtrack[hit]-globPref);
869  }
870  }
871 // cout << "trajectory: " << trajectoryState << endl;
872  const FreeTrajectoryState ftsLas = FreeTrajectoryState(globPtrack[hit],trajectoryState,0,magneticField);
873  tsosLas.push_back(TrajectoryStateOnSurface(ftsLas,gd[hit]->surface(),
875 }
876 
877 
878 //---------------------- set beam parameters for fittedBeams ---------------------------------
880  unsigned int &hitsAtTecPlus, unsigned int &nFitParams,
881  double &offset, double &slope, vector<GlobalPoint> &globPtrack,
882  double &bsAngleParam, double &chi2)
883 {
884  // set beam parameters for beam output
885  unsigned int paramType(0);
886  if(!fitBeamSplitters_) paramType = 1;
887  if(beam.isAlignmentTube() && hitsAtTecPlus == 0) paramType = 0;
888 // const unsigned int nPedeParams = nFitParams + paramType;
889 
890  // test without BS params
891  const unsigned int nPedeParams(nFitParams);
892 // cout << "number of Pede parameters: " << nPedeParams << endl;
893 
894  std::vector<TkFittedLasBeam::Scalar> params(nPedeParams);
895  params[0] = offset;
896  params[1] = slope;
897  // no BS parameter for AT beams without TECplus hits
898 // if(beam.isTecInternal() || hitsAtTecPlus > 0) params[2] = bsAngleParam;
899 
900  AlgebraicMatrix derivatives(gHitZprime.size(), nPedeParams);
901  // fill derivatives matrix with local track derivatives
902  for(unsigned int hit = 0; hit < gHitZprime.size(); ++hit){
903 
904  // d(delta phi)/d(offset) is identical for every hit
905  derivatives[hit][0] = 1.0;
906 
907  // d(delta phi)/d(slope) and d(delta phi)/d(bsAngleParam) depend on parametrizations
908  // TECplus
909  if(beam.isTecInternal(1)){
910  derivatives[hit][1] = globPtrack[hit].z();
911 // if(gHitZprime[hit] < gBeamSplitterZprime){
912 // derivatives[hit][2] = 0.0;
913 // }
914 // else{
915 // derivatives[hit][2] = - (globPtrack[hit].z() - gBeamSplitterZprime) / gBeamR;
916 // }
917  }
918  // TECminus
919  else if(beam.isTecInternal(-1)){
920  derivatives[hit][1] = globPtrack[hit].z();
921 // if(gHitZprime[hit] > gBeamSplitterZprime){
922 // derivatives[hit][2] = 0.0;
923 // }
924 // else{
925 // derivatives[hit][2] = (globPtrack[hit].z() - gBeamSplitterZprime) / gBeamR;
926 // }
927  }
928  // ATs
929  else{
930  // TECminus
932  derivatives[hit][1] = globPtrack[hit].z();
933 // if(hitsAtTecPlus > 0){
934 // derivatives[hit][2] = 0.0;
935 // }
936  }
937  // TECplus
938  else if(gHitZprime[hit] > gBeamSplitterZprime){
939  derivatives[hit][1] = globPtrack[hit].z();
940 // if(hitsAtTecPlus > 0){
941 // derivatives[hit][2] = - (globPtrack[hit].z() - gBeamSplitterZprime) / gBeamR;
942 // }
943  }
944  // Barrel
945  else{
946  derivatives[hit][1] = globPtrack[hit].z() - gBarrelModuleOffset[hit-gHitsAtTecMinus];
947 // if(hitsAtTecPlus > 0){
948 // derivatives[hit][2] = 0.0;
949 // }
950  }
951  }
952  }
953 
954  unsigned int firstFixedParam(covMatrix.num_col()); // FIXME! --> no, is fine!!!
955 // unsigned int firstFixedParam = nPedeParams - 1;
956 // if(beam.isAlignmentTube() && hitsAtTecPlus == 0) firstFixedParam = nPedeParams;
957 // cout << "first fixed parameter: " << firstFixedParam << endl;
958  // set fit results
959  beam.setParameters(paramType, params, covMatrix, derivatives, firstFixedParam, chi2);
960 
961  return true; // return false in case of problems
962 }
963 
964 
965 //---------------------------------------------------------------------------------------
966 //define this as a plug-in
ESHandle< MagneticField > fieldHandle
static vector< double > gHitZprime
static float gTOBparam
bool getByLabel(std::string const &label, Handle< PROD > &result) const
Definition: Run.h:201
const TrackerGeomDet * idToDetUnit(DetId) const
Return the pointer to the GeomDetUnit corresponding to a given DetId.
static double gBeamR
static double tecMinusFunction(double *x, double *par)
static double tecPlusFunction(double *x, double *par)
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:17
TkLasBeamFitter(const edm::ParameterSet &config)
static const double slope[3]
Global3DPoint GlobalPoint
Definition: GlobalPoint.h:10
bool isRing6(void) const
true if this beam hits TEC R6 (last digit of beamId)
Definition: TkLasBeam.h:49
def setup(process, global_tag, zero_tesla=False)
Definition: GeneralSetup.py:1
static vector< double > gBarrelModuleRadius
T * make(const Args &...args) const
make new ROOT object
Definition: TFileService.h:64
virtual LocalPoint localPosition() const
Definition: config.py:1
bool fitBeam(TkFittedLasBeam &beam, AlgebraicSymMatrix &covMatrix, unsigned int &hitsAtTecPlus, unsigned int &nFitParams, double &offset, double &slope, vector< GlobalPoint > &globPtrack, double &bsAngleParam, double &chi2)
static bool gFitBeamSplitters
bool isTecInternal(int side=0) const
true if this is a TEC internal beam (from 10^2 digit of beamId). side parameter: -1 = ask if TEC-...
Definition: TkLasBeam.cc:4
Handle< TkLasBeamCollection > laserBeams
T x() const
Cartesian x coordinate.
static bool gIsInnerBarrel
int iEvent
Definition: GenABIO.cc:230
virtual void endRunProduce(edm::Run &run, const edm::EventSetup &setup) override
unsigned int nAtParameters_
CLHEP::HepMatrix AlgebraicMatrix
unsigned int getBeamId(void) const
return the full beam identifier
Definition: TkLasBeam.h:25
T z() const
Definition: PV3DBase.h:64
void globalTrackPoint(TkFittedLasBeam &beam, unsigned int &hit, unsigned int &hitsAtTecPlus, double &trackPhi, double &trackPhiRef, std::vector< GlobalPoint > &globHit, std::vector< GlobalPoint > &globPtrack, GlobalPoint &globPref, std::vector< double > &hitPhiError)
static double gBeamSplitterZprime
std::vector< SiStripLaserRecHit2D >::const_iterator end(void) const
access iterator to the collection of hits
Definition: TkLasBeam.h:34
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
virtual void produce(edm::Event &event, const edm::EventSetup &setup) override
std::vector< SiStripLaserRecHit2D >::const_iterator begin(void) const
access iterator to the collection of hits
Definition: TkLasBeam.h:31
static unsigned int gHitsAtTecMinus
void fitter(TkFittedLasBeam &beam, AlgebraicSymMatrix &covMatrix, unsigned int &hitsAtTecPlus, unsigned int &nFitParams, std::vector< double > &hitPhi, std::vector< double > &hitPhiError, std::vector< double > &hitZprimeError, double &zMin, double &zMax, double &bsAngleParam, double &offset, double &offsetError, double &slope, double &slopeError, double &phiAtMinusParam, double &phiAtPlusParam, double &atThetaSplitParam)
const edm::InputTag src_
const SiStripDetId & getDetId(void) const
void buildTrajectory(TkFittedLasBeam &beam, unsigned int &hit, vector< const GeomDetUnit * > &gd, std::vector< GlobalPoint > &globPtrack, vector< TrajectoryStateOnSurface > &tsosLas, GlobalPoint &globPref)
static double gBSparam
const T & get() const
Definition: EventSetup.h:56
void put(std::unique_ptr< PROD > product)
Put a new product.
Definition: Run.h:111
static vector< double > gBarrelModuleOffset
ESHandle< TrackerGeometry > geometry
T perp() const
Magnitude of transverse component.
HLT enums.
void trackPhi(TkFittedLasBeam &beam, unsigned int &hit, double &trackPhi, double &trackPhiRef, double &offset, double &slope, double &bsAngleParam, double &phiAtMinusParam, double &phiAtPlusParam, double &atThetaSplitParam, std::vector< GlobalPoint > &globHit)
col
Definition: cuy.py:1008
CLHEP::HepSymMatrix AlgebraicSymMatrix
static float gTIBparam
static double atFunction(double *x, double *par)
void getLasBeams(TkFittedLasBeam &beam, vector< TrajectoryStateOnSurface > &tsosLas)
void getLasHits(TkFittedLasBeam &beam, const SiStripLaserRecHit2D &hit, vector< const GeomDetUnit * > &gd, vector< GlobalPoint > &globHit, unsigned int &hitsAtTecPlus)
edm::Service< TFileService > fs
T const * product() const
Definition: ESHandle.h:86
std::vector< SiStripLaserRecHit2D >::const_iterator const_iterator
Definition: TkLasBeam.h:16
bool isAlignmentTube(void) const
true if this is an AT beam (from 10^2 digit of beamId)
Definition: TkLasBeam.h:46
def move(src, dest)
Definition: eostools.py:510
Definition: event.py:1
Definition: Run.h:42
Global3DVector GlobalVector
Definition: GlobalVector.h:10
void setParameters(unsigned int parametrisation, const std::vector< Scalar > &params, const AlgebraicSymMatrix &paramCovariance, const AlgebraicMatrix &derivatives, unsigned int firstFixedParam, float chi2)
static double gBeamZ0