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Pi0FixedMassWindowCalibration.cc
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2 
3 // System include files
4 
5 // Framework
6 
7 
8 // Conditions database
9 
12 
13 // Reconstruction Classes
16 // Geometry
23 
24 // EgammaCoreTools
27 
28 //const double Pi0Calibration::PDGPi0Mass = 0.1349766;
29 
30 using namespace std;
31 
32 //_____________________________________________________________________________
33 
35  theMaxLoops( iConfig.getUntrackedParameter<unsigned int>("maxLoops",0) ),
36  ecalHitsProducer_( iConfig.getParameter< std::string > ("ecalRecHitsProducer") ),
37  barrelHits_( iConfig.getParameter< std::string > ("barrelHitCollection") )
38 {
39 
40  std::cout << "[Pi0FixedMassWindowCalibration] Constructor "<<std::endl;
41  // The verbosity level
42  std::string verbosityString = iConfig.getParameter<std::string>("VerbosityLevel");
43  if (verbosityString == "DEBUG") verbosity = IslandClusterAlgo::pDEBUG;
44  else if (verbosityString == "WARNING") verbosity = IslandClusterAlgo::pWARNING;
45  else if (verbosityString == "INFO") verbosity = IslandClusterAlgo::pINFO;
47 
48  // The names of the produced cluster collections
49  barrelClusterCollection_ = iConfig.getParameter<std::string>("barrelClusterCollection");
50 
51  // Island algorithm parameters
52  double barrelSeedThreshold = iConfig.getParameter<double>("IslandBarrelSeedThr");
53  double endcapSeedThreshold = iConfig.getParameter<double>("IslandEndcapSeedThr");
54 
55 
56  // Selection algorithm parameters
57  selePi0PtGammaOneMin_ = iConfig.getParameter<double>("selePi0PtGammaOneMin");
58  selePi0PtGammaTwoMin_ = iConfig.getParameter<double>("selePi0PtGammaTwoMin");
59 
60  selePi0DRBelt_ = iConfig.getParameter<double>("selePi0DRBelt");
61  selePi0DetaBelt_ = iConfig.getParameter<double>("selePi0DetaBelt");
62 
63  selePi0PtPi0Min_ = iConfig.getParameter<double>("selePi0PtPi0Min");
64 
65  selePi0S4S9GammaOneMin_ = iConfig.getParameter<double>("selePi0S4S9GammaOneMin");
66  selePi0S4S9GammaTwoMin_ = iConfig.getParameter<double>("selePi0S4S9GammaTwoMin");
67  selePi0S9S25GammaOneMin_ = iConfig.getParameter<double>("selePi0S9S25GammaOneMin");
68  selePi0S9S25GammaTwoMin_ = iConfig.getParameter<double>("selePi0S9S25GammaTwoMin");
69 
70  selePi0EtBeltIsoRatioMax_ = iConfig.getParameter<double>("selePi0EtBeltIsoRatioMax");
71 
72  selePi0MinvMeanFixed_ = iConfig.getParameter<double>("selePi0MinvMeanFixed");
73  selePi0MinvSigmaFixed_ = iConfig.getParameter<double>("selePi0MinvSigmaFixed");
74 
75 
76 
77 
78  // Parameters for the position calculation:
80  iConfig.getParameter<edm::ParameterSet>("posCalcParameters");
81  posCalculator_ = PositionCalc(posCalcParameters);
82  shapeAlgo_ = ClusterShapeAlgo(posCalcParameters);
83  clustershapecollectionEB_ = iConfig.getParameter<std::string>("clustershapecollectionEB");
84 
85  //AssociationMap
86  barrelClusterShapeAssociation_ = iConfig.getParameter<std::string>("barrelShapeAssociation");
87 
88  island_p = new IslandClusterAlgo(barrelSeedThreshold, endcapSeedThreshold, posCalculator_,verbosity);
89 
90  theParameterSet=iConfig;
91 
92 
93 }
94 
95 
96 //_____________________________________________________________________________
97 // Close files, etc.
98 
100 {
101 
102 }
103 
104 //_____________________________________________________________________________
105 // Initialize algorithm
106 
108 {
109 
110  //std::cout << "[Pi0FixedMassWindowCalibration] beginOfJob "<<std::endl;
111 
112  isfirstcall_=true;
113 
114 
115 
116 }
117 
118 
120 {
121 
122  std::cout << "[Pi0FixedMassWindowCalibration] endOfJob"<<endl;
123 
124  // Write new calibration constants
125 
126  Pi0CalibXMLwriter barrelWriter(EcalBarrel,99);
127 
128  std::vector<DetId>::const_iterator barrelIt=barrelCells.begin();
129  for (; barrelIt!=barrelCells.end(); barrelIt++) {
130  EBDetId eb(*barrelIt);
131  int ieta = eb.ieta();
132  int iphi = eb.iphi();
133  int sign = eb.zside()>0 ? 1 : 0;
134  barrelWriter.writeLine(eb,newCalibs_barl[abs(ieta)-1][iphi-1][sign]);
135  }
136 
137 }
138 
139 //_____________________________________________________________________________
140 // Called at beginning of loop
142 {
143 
144  for (int sign=0; sign<2; sign++) {
145  for (int ieta=0; ieta<85; ieta++) {
146  for (int iphi=0; iphi<360; iphi++) {
147  wxtals[ieta][iphi][sign]=0.;
148  mwxtals[ieta][iphi][sign]=0.;
149  }
150  }
151  }
152  std::cout << "[Pi0FixedMassWindowCalibration] Starting loop number " << iLoop<<std::endl;
153 
154 }
155 
156 
157 //_____________________________________________________________________________
158 // Called at end of loop
159 
162 {
163  std::cout << "[Pi0FixedMassWindowCalibration] Ending loop " << iLoop<<std::endl;
164 
165  for (int sign=0; sign<2; sign++) {
166  for (int ieta=0; ieta<85; ieta++) {
167  for (int iphi=0; iphi<360; iphi++) {
168 
169  if (wxtals[ieta][iphi][sign] == 0 )
170  {
171  newCalibs_barl[ieta][iphi][sign]=oldCalibs_barl[ieta][iphi][sign];
172  } else {
173  newCalibs_barl[ieta][iphi][sign]=oldCalibs_barl[ieta][iphi][sign]*(mwxtals[ieta][iphi][sign]/wxtals[ieta][iphi][sign]);
174  }
175  cout<< " New calibration constant: ieta iphi sign - old,mwxtals,wxtals,new: "<<ieta<<" "<<iphi<<" "<<sign<<" - "<<oldCalibs_barl[ieta][iphi][sign]<<" "<<mwxtals[ieta][iphi][sign]<<" "<<wxtals[ieta][iphi][sign]<<" "<<newCalibs_barl[ieta][iphi][sign]<<endl;
176 
177  }
178  }
179  }
180 
181  Pi0CalibXMLwriter barrelWriter(EcalBarrel,iLoop+1);
182 
183  std::vector<DetId>::const_iterator barrelIt=barrelCells.begin();
184  for (; barrelIt!=barrelCells.end(); barrelIt++) {
185  EBDetId eb(*barrelIt);
186  int ieta = eb.ieta();
187  int iphi = eb.iphi();
188  int sign = eb.zside()>0 ? 1 : 0;
189  barrelWriter.writeLine(eb,newCalibs_barl[abs(ieta)-1][iphi-1][sign]);
190  if (iphi==1) {
191  std::cout << "Calib constant for barrel crystal "
192  << " (" << ieta << "," << iphi << ") changed from "
193  << oldCalibs_barl[abs(ieta)-1][iphi-1][sign] << " to "
194  << newCalibs_barl[abs(ieta)-1][iphi-1][sign] << std::endl;
195  }
196  }
197 
198  // replace old calibration constants with new one
199 
200  for (int sign=0; sign<2; sign++) {
201  for (int ieta=0; ieta<85; ieta++) {
202  for (int iphi=0; iphi<360; iphi++) {
203  oldCalibs_barl[ieta][iphi][sign]=newCalibs_barl[ieta][iphi][sign];
204  newCalibs_barl[ieta][iphi][sign]=0;
205  }
206  }
207  }
208 
209 
210  if ( iLoop == theMaxLoops-1 || iLoop >= theMaxLoops ) return kStop;
211  else return kContinue;
212 }
213 
214 //_____________________________________________________________________________
215 // Called at each event
216 
219  const edm::EventSetup& setup )
220 {
221  using namespace edm;
222  using namespace std;
223 
224  // this chunk used to belong to beginJob(isetup). Moved here
225  // with the beginJob without arguments migration
226 
227  if (isfirstcall_){
228  // initialize arrays
229 
230  for (int sign=0; sign<2; sign++) {
231  for (int ieta=0; ieta<85; ieta++) {
232  for (int iphi=0; iphi<360; iphi++) {
233  oldCalibs_barl[ieta][iphi][sign]=0.;
234  newCalibs_barl[ieta][iphi][sign]=0.;
235  wxtals[ieta][iphi][sign]=0.;
236  mwxtals[ieta][iphi][sign]=0.;
237  }
238  }
239  }
240 
241  // get initial constants out of DB
242 
245 
246  try {
247  setup.get<EcalIntercalibConstantsRcd>().get(pIcal);
248  std::cout << "Taken EcalIntercalibConstants" << std::endl;
249  imap = pIcal.product()->getMap();
250  std::cout << "imap.size() = " << imap.size() << std::endl;
251  } catch ( std::exception& ex ) {
252  std::cerr << "Error! can't get EcalIntercalibConstants " << std::endl;
253  }
254 
255  // get the ecal geometry:
256  edm::ESHandle<CaloGeometry> geoHandle;
257  setup.get<CaloGeometryRecord>().get(geoHandle);
258  const CaloGeometry& geometry = *geoHandle;
259  //const CaloSubdetectorGeometry *barrelGeometry = geometry.getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
260 
261  // loop over all barrel crystals
263  std::vector<DetId>::const_iterator barrelIt;
264  for (barrelIt=barrelCells.begin(); barrelIt!=barrelCells.end(); barrelIt++) {
265  EBDetId eb(*barrelIt);
266 
267  // get the initial calibration constants
269  if ( itcalib == imap.end() ) {
270  // FIXME -- throw error
271  }
272  EcalIntercalibConstant calib = (*itcalib);
273  int sign = eb.zside()>0 ? 1 : 0;
274  oldCalibs_barl[abs(eb.ieta())-1][eb.iphi()-1][sign] = calib;
275  if (eb.iphi()==1) std::cout << "Read old constant for crystal "
276  << " (" << eb.ieta() << "," << eb.iphi()
277  << ") : " << calib << std::endl;
278 
279 
280 
281  }
282  isfirstcall_=false;
283  }
284 
285 
286 
287  nevent++;
288 
289  if ((nevent<100 && nevent%10==0)
290  ||(nevent<1000 && nevent%100==0)
291  ||(nevent<10000 && nevent%100==0)
292  ||(nevent<100000 && nevent%1000==0)
293  ||(nevent<10000000 && nevent%1000==0))
294  std::cout << "[Pi0FixedMassWindowCalibration] Events processed: "<<nevent<<std::endl;
295 
296  recHitsEB_map = new std::map<DetId, EcalRecHit>();
297 
299 
300  int nRecHitsEB=0;
301  Handle<EcalRecHitCollection> pEcalRecHitBarrelCollection;
302  event.getByLabel(ecalHitsProducer_, barrelHits_, pEcalRecHitBarrelCollection);
303  const EcalRecHitCollection* ecalRecHitBarrelCollection = pEcalRecHitBarrelCollection.product();
304  cout << " ECAL Barrel RecHits # "<< ecalRecHitBarrelCollection->size() <<endl;
305  for(EcalRecHitCollection::const_iterator aRecHitEB = ecalRecHitBarrelCollection->begin(); aRecHitEB != ecalRecHitBarrelCollection->end(); aRecHitEB++) {
306  //cout << " ECAL Barrel RecHit #,E,time,det,subdetid: "<<nRecHitsEB<<" "<<aRecHitEB->energy()<<" "<<aRecHitEB->time()<<" "<<aRecHitEB->detid().det()<<" "<<aRecHitEB->detid().subdetId()<<endl;
307 
308 
309  EBDetId ebrhdetid = aRecHitEB->detid();
310  //cout << " EBDETID: z,ieta,iphi "<<ebrhdetid.zside()<<" "<<ebrhdetid.ieta()<<" "<<ebrhdetid.iphi()<<endl;
311  //cout << " EBDETID: tower_ieta,tower_iphi "<<ebrhdetid.tower_ieta()<<" "<<ebrhdetid.tower_iphi()<<endl;
312  //cout << " EBDETID: iSM, ic "<<ebrhdetid.ism()<<" "<<ebrhdetid.ic()<<endl;
313 
314  int sign = ebrhdetid.zside()>0 ? 1 : 0;
315  EcalRecHit aHit(aRecHitEB->id(),aRecHitEB->energy()*oldCalibs_barl[abs(ebrhdetid.ieta())-1][ebrhdetid.iphi()-1][sign],aRecHitEB->time());
316  recalibEcalRecHitCollection->push_back(aHit);
317 
318  nRecHitsEB++;
319 
320  }
321 
322  // cout<<" Recalib size: "<<recalibEcalRecHitCollection->size()<<endl;
323  int irecalib=0;
324  for(EcalRecHitCollection::const_iterator aRecHitEB = recalibEcalRecHitCollection->begin(); aRecHitEB != recalibEcalRecHitCollection->end(); aRecHitEB++) {
325  //cout << " [recalibrated] ECAL Barrel RecHit #,E,time,det,subdetid: "<<irecalib<<" "<<aRecHitEB->energy()<<" "<<aRecHitEB->time()<<" "<<aRecHitEB->detid().det()<<" "<<aRecHitEB->detid().subdetId()<<endl;
326 
327  // EBDetId ebrhdetid = aRecHitEB->detid();
328  //cout << " [recalibrated] EBDETID: z,ieta,iphi "<<ebrhdetid.zside()<<" "<<ebrhdetid.ieta()<<" "<<ebrhdetid.iphi()<<endl;
329  //cout << " [recalibrated] EBDETID: tower_ieta,tower_iphi "<<ebrhdetid.tower_ieta()<<" "<<ebrhdetid.tower_iphi()<<endl;
330  //cout << " [recalibrated] EBDETID: iSM, ic "<<ebrhdetid.ism()<<" "<<ebrhdetid.ic()<<endl;
331 
332  std::pair<DetId, EcalRecHit> map_entry(aRecHitEB->id(), *aRecHitEB);
333  recHitsEB_map->insert(map_entry);
334 
335 
336  irecalib++;
337 
338  }
339 
340 
341  // get the geometry and topology from the event setup:
342  edm::ESHandle<CaloGeometry> geoHandle;
343  setup.get<CaloGeometryRecord>().get(geoHandle);
344 
345  const CaloSubdetectorGeometry *geometry_p;
346  CaloSubdetectorTopology *topology_p;
347 
348  std::string clustershapetag;
349  geometry_p = geoHandle->getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
350  topology_p = new EcalBarrelTopology(geoHandle);
351 
352  const CaloSubdetectorGeometry *geometryES_p;
353  geometryES_p = geoHandle->getSubdetectorGeometry(DetId::Ecal, EcalPreshower);
354 
355  /*
356  reco::BasicClusterCollection clusters;
357  clusters = island_p->makeClusters(ecalRecHitBarrelCollection,geometry_p,topology_p,geometryES_p,IslandClusterAlgo::barrel);
358 
359  //Create associated ClusterShape objects.
360  std::vector <reco::ClusterShape> ClusVec;
361  for (int erg=0;erg<int(clusters.size());++erg){
362  reco::ClusterShape TestShape = shapeAlgo_.Calculate(clusters[erg],ecalRecHitBarrelCollection,geometry_p,topology_p);
363  ClusVec.push_back(TestShape);
364  }
365 
366  //Put clustershapes in event, but retain a Handle on them.
367  std::auto_ptr<reco::ClusterShapeCollection> clustersshapes_p(new reco::ClusterShapeCollection);
368  clustersshapes_p->assign(ClusVec.begin(), ClusVec.end());
369 
370  cout<<"[Pi0Calibration] Basic Cluster collection size: "<<clusters.size()<<endl;
371  cout<<"[Pi0Calibration] Basic Cluster Shape Collection size: "<<clustersshapes_p->size()<<endl;
372 
373  int iClus=0;
374  for(reco::BasicClusterCollection::const_iterator aClus = clusters.begin(); aClus != clusters.end(); aClus++) {
375  cout<<" CLUSTER : #,NHits,e,et,eta,phi,e2x2,e3x3,e5x5: "<<iClus<<" "<<aClus->getHitsByDetId().size()<<" "<<aClus->energy()<<" "<<aClus->energy()*sin(aClus->position().theta())<<" "<<aClus->position().eta()<<" "<<aClus->position().phi()<<" "<<(*clustersshapes_p)[iClus].e2x2()<<" "<<(*clustersshapes_p)[iClus].e3x3()<<" "<<(*clustersshapes_p)[iClus].e5x5()<<endl;
376  iClus++;
377  }
378  */
379 
380  // recalibrated clusters
381  reco::BasicClusterCollection clusters_recalib;
382  clusters_recalib = island_p->makeClusters(recalibEcalRecHitCollection,geometry_p,topology_p,geometryES_p,IslandClusterAlgo::barrel);
383 
384  //Create associated ClusterShape objects.
385  std::vector <reco::ClusterShape> ClusVec_recalib;
386  for (int erg=0;erg<int(clusters_recalib.size());++erg){
387  reco::ClusterShape TestShape_recalib = shapeAlgo_.Calculate(clusters_recalib[erg],recalibEcalRecHitCollection,geometry_p,topology_p);
388  ClusVec_recalib.push_back(TestShape_recalib);
389  }
390 
391  //Put clustershapes in event, but retain a Handle on them.
392  std::auto_ptr<reco::ClusterShapeCollection> clustersshapes_p_recalib(new reco::ClusterShapeCollection);
393  clustersshapes_p_recalib->assign(ClusVec_recalib.begin(), ClusVec_recalib.end());
394 
395  cout<<"[Pi0FixedMassWindowCalibration][recalibration] Basic Cluster collection size: "<<clusters_recalib.size()<<endl;
396  cout<<"[Pi0FixedMassWindowCalibration][recalibration] Basic Cluster Shape Collection size: "<<clustersshapes_p_recalib->size()<<endl;
397 
398 
399  // pizero selection
400 
401  // Get ECAL Barrel Island Basic Clusters collection
402  // ECAL Barrel Island Basic Clusters
403  static const int MAXBCEB = 200;
404  static const int MAXBCEBRH = 200;
405  int nIslandBCEB;
406  float eIslandBCEB[MAXBCEB];
407  float etIslandBCEB[MAXBCEB];
408  float etaIslandBCEB[MAXBCEB];
409  float phiIslandBCEB[MAXBCEB];
410  float e2x2IslandBCEB[MAXBCEB];
411  float e3x3IslandBCEB[MAXBCEB];
412  float e5x5IslandBCEB[MAXBCEB];
413  // indexes to the RecHits assiciated with
414  // ECAL Barrel Island Basic Clusters
415  int nIslandBCEBRecHits[MAXBCEB];
416  // int indexIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
417  int ietaIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
418  int iphiIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
419  int zsideIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
420  float eIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
421 
422  nIslandBCEB=0;
423  for(int i=0; i<MAXBCEB; i++){
424  eIslandBCEB[i] = 0;
425  etIslandBCEB[i] = 0;
426  etaIslandBCEB[i] = 0;
427  phiIslandBCEB[i] = 0;
428  e2x2IslandBCEB[i] = 0;
429  e3x3IslandBCEB[i] = 0;
430  e5x5IslandBCEB[i] = 0;
431  nIslandBCEBRecHits[i] = 0;
432  for(int j=0;j<MAXBCEBRH;j++){
433  // indexIslandBCEBRecHits[i][j] = 0;
434  ietaIslandBCEBRecHits[i][j] = 0;
435  iphiIslandBCEBRecHits[i][j] = 0;
436  zsideIslandBCEBRecHits[i][j] = 0;
437  eIslandBCEBRecHits[i][j] = 0;
438  }
439  }
440 
441 
442  int iClus_recalib=0;
443  for(reco::BasicClusterCollection::const_iterator aClus = clusters_recalib.begin(); aClus != clusters_recalib.end(); aClus++) {
444  cout<<" CLUSTER [recalibration] : #,NHits,e,et,eta,phi,e2x2,e3x3,e5x5: "<<iClus_recalib<<" "<<aClus->size()<<" "<<aClus->energy()<<" "<<aClus->energy()*sin(aClus->position().theta())<<" "<<aClus->position().eta()<<" "<<aClus->position().phi()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e2x2()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e3x3()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e5x5()<<endl;
445 
446  eIslandBCEB[nIslandBCEB] = aClus->energy();
447  etIslandBCEB[nIslandBCEB] = aClus->energy()*sin(aClus->position().theta());
448  etaIslandBCEB[nIslandBCEB] = aClus->position().eta();
449  phiIslandBCEB[nIslandBCEB] = aClus->position().phi();
450 
451  e2x2IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e2x2();
452  e3x3IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e3x3();
453  e5x5IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e5x5();
454 
455  nIslandBCEBRecHits[nIslandBCEB] = aClus->size();
456 
457  std::vector<std::pair< DetId,float> > hits = aClus->hitsAndFractions();
458  std::vector<std::pair< DetId,float> >::iterator hit;
459  std::map<DetId, EcalRecHit>::iterator aHit;
460 
461  int irhcount=0;
462  for(hit = hits.begin(); hit != hits.end(); hit++)
463  {
464  // need to get hit by DetID in order to get energy
465  aHit = recHitsEB_map->find((*hit).first);
466  //cout << " RecHit #: "<<irhcount<<" from Basic Cluster with Energy: "<<aHit->second.energy()<<endl;
467 
468  EBDetId sel_rh = aHit->second.detid();
469  //cout << " RecHit: z,ieta,iphi "<<sel_rh.zside()<<" "<<sel_rh.ieta()<<" "<<sel_rh.iphi()<<endl;
470  //cout << " RecHit: tower_ieta,tower_iphi "<<sel_rh.tower_ieta()<<" "<<sel_rh.tower_iphi()<<endl;
471  //cout << " RecHit: iSM, ic "<<sel_rh.ism()<<" "<<sel_rh.ic()<<endl;
472 
473  ietaIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.ieta();
474  iphiIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.iphi();
475  zsideIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.zside();
476  eIslandBCEBRecHits[nIslandBCEB][irhcount] = aHit->second.energy();
477 
478  irhcount++;
479  }
480  nIslandBCEB++;
481  iClus_recalib++;
482 
483 
484  }
485 
486  // Selection, based on ECAL Barrel Basic Clusters
487 
488  if (nIslandBCEB > 1)
489  {
490  for(int i=0 ; i<nIslandBCEB ; i++)
491  {
492  for(int j=i+1 ; j<nIslandBCEB ; j++)
493  {
494 
495  if( etIslandBCEB[i]>selePi0PtGammaOneMin_ && etIslandBCEB[j]>selePi0PtGammaOneMin_)
496  {
497 
498  float theta_0 = 2. * atan(exp(-etaIslandBCEB[i]));
499  float theta_1 = 2. * atan(exp(-etaIslandBCEB[j]));
500 
501  float p0x = eIslandBCEB[i] * sin(theta_0) * cos(phiIslandBCEB[i]);
502  float p1x = eIslandBCEB[j] * sin(theta_1) * cos(phiIslandBCEB[j]);
503 
504  float p0y = eIslandBCEB[i] * sin(theta_0) * sin(phiIslandBCEB[i]);
505  float p1y = eIslandBCEB[j] * sin(theta_1) * sin(phiIslandBCEB[j]);
506 
507  float p0z = eIslandBCEB[i] * cos(theta_0);
508  float p1z = eIslandBCEB[j] * cos(theta_1);
509 
510  float pi0_px = p0x + p1x;
511  float pi0_py = p0y + p1y;
512  float pi0_pz = p0z + p1z;
513 
514  float pi0_ptot = sqrt (pi0_px*pi0_px + pi0_py*pi0_py + pi0_pz*pi0_pz);
515 
516  float pi0_theta = acos(pi0_pz/pi0_ptot);
517  float pi0_eta = -log(tan(pi0_theta/2));
518  float pi0_phi = atan(pi0_py/pi0_px);
519  //cout << " pi0_theta, pi0_eta, pi0_phi "<<pi0_theta<<" "<<pi0_eta<<" "<<pi0_phi<<endl;
520 
521  // belt isolation
522 
523  float et_belt=0;
524  for(Int_t k=0 ; k<nIslandBCEB ; k++)
525  {
526  if( (k != i) && (k != j) )
527  {
528  float dr_pi0_k = sqrt( (etaIslandBCEB[k]-pi0_eta)*(etaIslandBCEB[k]-pi0_eta) + (phiIslandBCEB[k]-pi0_phi)*(phiIslandBCEB[k]-pi0_phi) );
529  float deta_pi0_k = fabs(etaIslandBCEB[k]-pi0_eta);
530  if ( (dr_pi0_k<selePi0DRBelt_) && (deta_pi0_k<selePi0DetaBelt_) ) et_belt = et_belt + etIslandBCEB[k];
531  }
532  }
533 
534 
535  float pt_pi0 = sqrt( (p0x+p1x)*(p0x+p1x) + (p0y+p1y)*(p0y+p1y));
536  //float dr_pi0 = sqrt ( (etaIslandBCEB[i]-etaIslandBCEB[j])*(etaIslandBCEB[i]-etaIslandBCEB[j]) + (phiIslandBCEB[i]-phiIslandBCEB[j])*(phiIslandBCEB[i]-phiIslandBCEB[j]) );
537 
538  //cout <<" pi0 pt,dr: "<<pt_pi0<<" "<<dr_pi0<<endl;
539  if (pt_pi0 > selePi0PtPi0Min_)
540  {
541  float m_inv = sqrt ( (eIslandBCEB[i] + eIslandBCEB[j])*(eIslandBCEB[i] + eIslandBCEB[j]) - (p0x+p1x)*(p0x+p1x) - (p0y+p1y)*(p0y+p1y) - (p0z+p1z)*(p0z+p1z) );
542  cout <<" pi0 (pt>2.5 GeV) m_inv = "<<m_inv<<endl;
543 
544  float s4s9_1 = e2x2IslandBCEB[i]/e3x3IslandBCEB[i];
545  float s4s9_2 = e2x2IslandBCEB[j]/e3x3IslandBCEB[j];
546 
547  float s9s25_1 = e3x3IslandBCEB[i]/e5x5IslandBCEB[i];
548  float s9s25_2 = e3x3IslandBCEB[j]/e5x5IslandBCEB[j];
549 
550  //float s9Esc_1 = e3x3IslandBCEB[i]/eIslandBCEB[i];
551  //float s9Esc_2 = e3x3IslandBCEB[j]/eIslandBCEB[j];
552 
554  {
555  //good pizero candidate
557  {
558  //fill wxtals and mwxtals weights
559  cout<<" Pi0 Good candidate : minv = "<<m_inv<<endl;
560  for(int kk=0 ; kk<nIslandBCEBRecHits[i] ; kk++)
561  {
562  int ieta_xtal = ietaIslandBCEBRecHits[i][kk];
563  int iphi_xtal = iphiIslandBCEBRecHits[i][kk];
564  int sign = zsideIslandBCEBRecHits[i][kk]>0 ? 1 : 0;
565  wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + eIslandBCEBRecHits[i][kk]/e3x3IslandBCEB[i];
566  mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + (selePi0MinvMeanFixed_/m_inv)*(selePi0MinvMeanFixed_/m_inv)*(eIslandBCEBRecHits[i][kk]/e3x3IslandBCEB[i]);
567  cout<< "[Pi0FixedMassWindowCalibration] eta, phi, sign, e, e3x3, wxtals and mwxtals: "<<ieta_xtal<<" "<<iphi_xtal<<" "<<sign<<" "<<eIslandBCEBRecHits[i][kk]<<" "<<e3x3IslandBCEB[i]<<" "<<wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<" "<<mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<endl;
568  }
569 
570  for(int kk=0 ; kk<nIslandBCEBRecHits[j] ; kk++)
571  {
572  int ieta_xtal = ietaIslandBCEBRecHits[j][kk];
573  int iphi_xtal = iphiIslandBCEBRecHits[j][kk];
574  int sign = zsideIslandBCEBRecHits[j][kk]>0 ? 1 : 0;
575  wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + eIslandBCEBRecHits[j][kk]/e3x3IslandBCEB[j];
576  mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + (selePi0MinvMeanFixed_/m_inv)*(selePi0MinvMeanFixed_/m_inv)*(eIslandBCEBRecHits[j][kk]/e3x3IslandBCEB[j]);
577  cout<< "[Pi0FixedMassWindowCalibration] eta, phi, sign, e, e3x3, wxtals and mwxtals: "<<ieta_xtal<<" "<<iphi_xtal<<" "<<sign<<" "<<eIslandBCEBRecHits[j][kk]<<" "<<e3x3IslandBCEB[j]<<" "<<wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<" "<<mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<endl;
578  }
579 
580  }
581  }
582  }
583  }
584 
585 
586  } // End of the "j" loop over BCEB
587  } // End of the "i" loop over BCEB
588 
589 
590  } else {
591  cout<< " Not enough ECAL Barrel Basic Clusters: "<<nIslandBCEB<<endl;
592  }
593 
594 
595 
596 
597 
598 
599  return kContinue;
600 }
601 
602 // ----------------------------------------------------------------------------
T getParameter(std::string const &) const
const CaloSubdetectorGeometry * getSubdetectorGeometry(const DetId &id) const
access the subdetector geometry for the given subdetector directly
Definition: CaloGeometry.cc:44
void startingNewLoop(unsigned int iLoop) override
Called at beginning of loop.
void beginOfJob() override
Called at beginning of job.
Status endOfLoop(const edm::EventSetup &, unsigned int iLoop) override
Called at end of loop.
const self & getMap() const
void writeLine(EBDetId const &, float)
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::vector< EcalRecHit >::const_iterator const_iterator
def setup(process, global_tag, zero_tesla=False)
Definition: GeneralSetup.py:1
std::vector< ClusterShape > ClusterShapeCollection
collection of ClusterShape objects
IslandClusterAlgo::VerbosityLevel verbosity
int iphi() const
get the crystal iphi
Definition: EBDetId.h:53
uint32_t rawId() const
get the raw id
Definition: DetId.h:43
reco::ClusterShape Calculate(const reco::BasicCluster &passedCluster, const EcalRecHitCollection *hits, const CaloSubdetectorGeometry *geometry, const CaloSubdetectorTopology *topology)
MVATrainerComputer * calib
Definition: MVATrainer.cc:64
T sqrt(T t)
Definition: SSEVec.h:18
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
std::vector< reco::BasicCluster > makeClusters(const EcalRecHitCollection *hits, const CaloSubdetectorGeometry *geometry, const CaloSubdetectorTopology *topology_p, const CaloSubdetectorGeometry *geometryES_p, EcalPart ecalPart, bool regional=false, const std::vector< EcalEtaPhiRegion > &regions=std::vector< EcalEtaPhiRegion >())
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
int ieta() const
get the crystal ieta
Definition: EBDetId.h:51
const EcalRecHitCollection * ecalRecHitBarrelCollection
int k[5][pyjets_maxn]
const_iterator end() const
T const * product() const
Definition: Handle.h:81
const T & get() const
Definition: EventSetup.h:58
std::vector< Item >::const_iterator const_iterator
Status duringLoop(const edm::Event &, const edm::EventSetup &) override
Called at each event.
std::vector< BasicCluster > BasicClusterCollection
collection of BasicCluster objects
std::vector< DetId > getValidDetIds() const
Get the list of all valid detector ids.
Definition: CaloGeometry.cc:97
HLT enums.
size_type size() const
const_iterator find(uint32_t rawId) const
const_iterator end() const
std::map< DetId, EcalRecHit > * recHitsEB_map
Pi0FixedMassWindowCalibration(const edm::ParameterSet &iConfig)
Constructor.
~Pi0FixedMassWindowCalibration() override
Destructor.
T const * product() const
Definition: ESHandle.h:86
const EcalRecHitCollection * recalibEcalRecHitCollection
void endOfJob() override
Called at end of job.
const_iterator begin() const
Definition: event.py:1
int zside() const
get the z-side of the crystal (1/-1)
Definition: EBDetId.h:47
float EcalIntercalibConstant