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EtlSimHitsValidation.cc
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1 // -*- C++ -*-
2 //
3 // Package: Validation/MtdValidation
4 // Class: EtlSimHitsValidation
5 //
14 #include <string>
15 
20 
23 
27 
31 
36 
37 #include "MTDHit.h"
38 
40 public:
41  explicit EtlSimHitsValidation(const edm::ParameterSet&);
42  ~EtlSimHitsValidation() override;
43 
44  static void fillDescriptions(edm::ConfigurationDescriptions& descriptions);
45 
46 private:
47  void bookHistograms(DQMStore::IBooker&, edm::Run const&, edm::EventSetup const&) override;
48 
49  void analyze(const edm::Event&, const edm::EventSetup&) override;
50 
51  // ------------ member data ------------
52 
54  const float hitMinEnergy2Dis_;
55 
57 
60 
61  // --- histograms declaration
62 
65 
68 
72 
74 
80 
86 };
87 
88 // ------------ constructor and destructor --------------
90  : folder_(iConfig.getParameter<std::string>("folder")),
91  hitMinEnergy2Dis_(iConfig.getParameter<double>("hitMinimumEnergy2Dis")) {
92  etlSimHitsToken_ = consumes<CrossingFrame<PSimHit> >(iConfig.getParameter<edm::InputTag>("inputTag"));
93  mtdgeoToken_ = esConsumes<MTDGeometry, MTDDigiGeometryRecord>();
94  mtdtopoToken_ = esConsumes<MTDTopology, MTDTopologyRcd>();
95 }
96 
98 
99 // ------------ method called for each event ------------
101  using namespace edm;
102  using namespace geant_units::operators;
103 
104  auto geometryHandle = iSetup.getTransientHandle(mtdgeoToken_);
105  const MTDGeometry* geom = geometryHandle.product();
106 
107  auto etlSimHitsHandle = makeValid(iEvent.getHandle(etlSimHitsToken_));
108  MixCollection<PSimHit> etlSimHits(etlSimHitsHandle.product());
109 
110  std::unordered_map<uint32_t, MTDHit> m_etlHits[4];
111  std::unordered_map<uint32_t, std::set<int> > m_etlTrkPerCell[4];
112 
113  // --- Loop over the ETL SIM hits
114 
115  int idet = 999;
116 
117  size_t index(0);
118 
119  for (auto const& simHit : etlSimHits) {
120  index++;
121  LogDebug("EtlSimHitsValidation") << "SimHit # " << index << " detId " << simHit.detUnitId() << " ene "
122  << simHit.energyLoss() << " tof " << simHit.tof() << " tId " << simHit.trackId();
123 
124  // --- Use only hits compatible with the in-time bunch-crossing
125  if (simHit.tof() < 0 || simHit.tof() > 25.)
126  continue;
127 
128  ETLDetId id = simHit.detUnitId();
129  if ((id.zside() == -1) && (id.nDisc() == 1)) {
130  idet = 0;
131  } else if ((id.zside() == -1) && (id.nDisc() == 2)) {
132  idet = 1;
133  } else if ((id.zside() == 1) && (id.nDisc() == 1)) {
134  idet = 2;
135  } else if ((id.zside() == 1) && (id.nDisc() == 2)) {
136  idet = 3;
137  } else {
138  edm::LogWarning("EtlSimHitsValidation") << "Unknown ETL DetId configuration: " << id;
139  continue;
140  }
141 
142  m_etlTrkPerCell[idet][id.rawId()].insert(simHit.trackId());
143 
144  auto simHitIt = m_etlHits[idet].emplace(id.rawId(), MTDHit()).first;
145 
146  // --- Accumulate the energy (in MeV) of SIM hits in the same detector cell
147  (simHitIt->second).energy += convertUnitsTo(0.001_MeV, simHit.energyLoss());
148 
149  // --- Get the time of the first SIM hit in the cell
150  if ((simHitIt->second).time == 0 || simHit.tof() < (simHitIt->second).time) {
151  (simHitIt->second).time = simHit.tof();
152 
153  auto hit_pos = simHit.localPosition();
154  (simHitIt->second).x = hit_pos.x();
155  (simHitIt->second).y = hit_pos.y();
156  (simHitIt->second).z = hit_pos.z();
157  }
158  LogDebug("EtlSimHitsValidation") << "Registered in idet " << idet;
159 
160  } // simHit loop
161 
162  // ==============================================================================
163  // Histogram filling
164  // ==============================================================================
165 
166  for (int idet = 0; idet < 4; ++idet) { //two disks per side
167  meNhits_[idet]->Fill(m_etlHits[idet].size());
168  LogDebug("EtlSimHitsValidation") << "idet " << idet << " #hits " << m_etlHits[idet].size();
169 
170  for (auto const& hit : m_etlTrkPerCell[idet]) {
171  meNtrkPerCell_[idet]->Fill((hit.second).size());
172  }
173 
174  for (auto const& hit : m_etlHits[idet]) {
175  double weight = 1.0;
176  if ((hit.second).energy < hitMinEnergy2Dis_)
177  continue;
178  // --- Get the SIM hit global position
179  ETLDetId detId(hit.first);
180  DetId geoId = detId.geographicalId();
181  const MTDGeomDet* thedet = geom->idToDet(geoId);
182  if (thedet == nullptr)
183  throw cms::Exception("EtlSimHitsValidation") << "GeographicalID: " << std::hex << geoId.rawId() << " ("
184  << detId.rawId() << ") is invalid!" << std::dec << std::endl;
185 
186  Local3DPoint local_point(
187  convertMmToCm((hit.second).x), convertMmToCm((hit.second).y), convertMmToCm((hit.second).z));
188  const auto& global_point = thedet->toGlobal(local_point);
189 
190  if (detId.discSide() == 1) {
191  weight = -weight;
192  }
193 
194  // --- Fill the histograms
195 
196  meHitEnergy_[idet]->Fill((hit.second).energy);
197  meHitTime_[idet]->Fill((hit.second).time);
198  meHitXlocal_[idet]->Fill((hit.second).x);
199  meHitYlocal_[idet]->Fill((hit.second).y);
200  meHitZlocal_[idet]->Fill((hit.second).z);
201  meOccupancy_[idet]->Fill(global_point.x(), global_point.y(), weight);
202  meHitX_[idet]->Fill(global_point.x());
203  meHitY_[idet]->Fill(global_point.y());
204  meHitZ_[idet]->Fill(global_point.z());
205  meHitPhi_[idet]->Fill(global_point.phi());
206  meHitEta_[idet]->Fill(global_point.eta());
207  meHitTvsE_[idet]->Fill((hit.second).energy, (hit.second).time);
208  meHitEvsPhi_[idet]->Fill(global_point.phi(), (hit.second).energy);
209  meHitEvsEta_[idet]->Fill(global_point.eta(), (hit.second).energy);
210  meHitTvsPhi_[idet]->Fill(global_point.phi(), (hit.second).time);
211  meHitTvsEta_[idet]->Fill(global_point.eta(), (hit.second).time);
212 
213  } // hit loop
214 
215  } // idet loop
216 }
217 
218 // ------------ method for histogram booking ------------
220  edm::Run const& run,
221  edm::EventSetup const& iSetup) {
222  ibook.setCurrentFolder(folder_);
223 
224  // --- histograms booking
225 
226  meNhits_[0] = ibook.book1D("EtlNhitsZnegD1",
227  "Number of ETL cells with SIM hits (-Z, Single(topo1D)/First(topo2D) disk);N_{ETL cells}",
228  100,
229  0.,
230  5000.);
231  meNhits_[1] = ibook.book1D(
232  "EtlNhitsZnegD2", "Number of ETL cells with SIM hits (-Z, Second disk);N_{ETL cells}", 100, 0., 5000.);
233  meNhits_[2] = ibook.book1D("EtlNhitsZposD1",
234  "Number of ETL cells with SIM hits (+Z, Single(topo1D)/First(topo2D) disk);N_{ETL cells}",
235  100,
236  0.,
237  5000.);
238  meNhits_[3] = ibook.book1D(
239  "EtlNhitsZposD2", "Number of ETL cells with SIM hits (+Z, Second Disk);N_{ETL cells}", 100, 0., 5000.);
240  meNtrkPerCell_[0] = ibook.book1D("EtlNtrkPerCellZnegD1",
241  "Number of tracks per ETL sensor (-Z, Single(topo1D)/First(topo2D) disk);N_{trk}",
242  10,
243  0.,
244  10.);
245  meNtrkPerCell_[1] =
246  ibook.book1D("EtlNtrkPerCellZnegD2", "Number of tracks per ETL sensor (-Z, Second disk);N_{trk}", 10, 0., 10.);
247  meNtrkPerCell_[2] = ibook.book1D("EtlNtrkPerCellZposD1",
248  "Number of tracks per ETL sensor (+Z, Single(topo1D)/First(topo2D) disk);N_{trk}",
249  10,
250  0.,
251  10.);
252  meNtrkPerCell_[3] =
253  ibook.book1D("EtlNtrkPerCellZposD2", "Number of tracks per ETL sensor (+Z, Second disk);N_{trk}", 10, 0., 10.);
254  meHitEnergy_[0] = ibook.book1D(
255  "EtlHitEnergyZnegD1", "ETL SIM hits energy (-Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV]", 100, 0., 3.);
256  meHitEnergy_[1] =
257  ibook.book1D("EtlHitEnergyZnegD2", "ETL SIM hits energy (-Z, Second disk);E_{SIM} [MeV]", 100, 0., 3.);
258  meHitEnergy_[2] = ibook.book1D(
259  "EtlHitEnergyZposD1", "ETL SIM hits energy (+Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV]", 100, 0., 3.);
260  meHitEnergy_[3] =
261  ibook.book1D("EtlHitEnergyZposD2", "ETL SIM hits energy (+Z, Second disk);E_{SIM} [MeV]", 100, 0., 3.);
262  meHitTime_[0] = ibook.book1D(
263  "EtlHitTimeZnegD1", "ETL SIM hits ToA (-Z, Single(topo1D)/First(topo2D) disk);ToA_{SIM} [ns]", 100, 0., 25.);
264  meHitTime_[1] = ibook.book1D("EtlHitTimeZnegD2", "ETL SIM hits ToA (-Z, Second disk);ToA_{SIM} [ns]", 100, 0., 25.);
265  meHitTime_[2] = ibook.book1D(
266  "EtlHitTimeZposD1", "ETL SIM hits ToA (+Z, Single(topo1D)/First(topo2D) disk);ToA_{SIM} [ns]", 100, 0., 25.);
267  meHitTime_[3] = ibook.book1D("EtlHitTimeZposD2", "ETL SIM hits ToA (+Z, Second disk);ToA_{SIM} [ns]", 100, 0., 25.);
268 
269  meHitXlocal_[0] = ibook.book1D("EtlHitXlocalZnegD1",
270  "ETL SIM local X (-Z, Single(topo1D)/First(topo2D) disk);X_{SIM}^{LOC} [mm]",
271  100,
272  -25.,
273  25.);
274  meHitXlocal_[1] =
275  ibook.book1D("EtlHitXlocalZnegD2", "ETL SIM local X (-Z, Second disk);X_{SIM}^{LOC} [mm]", 100, -25., 25.);
276  meHitXlocal_[2] = ibook.book1D("EtlHitXlocalZposD1",
277  "ETL SIM local X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM}^{LOC} [mm]",
278  100,
279  -25.,
280  25.);
281  meHitXlocal_[3] =
282  ibook.book1D("EtlHitXlocalZposD2", "ETL SIM local X (+Z, Second disk);X_{SIM}^{LOC} [mm]", 100, -25., 25.);
283 
284  meHitYlocal_[0] = ibook.book1D("EtlHitYlocalZnegD1",
285  "ETL SIM local Y (-Z, Single(topo1D)/First(topo2D) disk);Y_{SIM}^{LOC} [mm]",
286  100,
287  -48.,
288  48.);
289  meHitYlocal_[1] =
290  ibook.book1D("EtlHitYlocalZnegD2", "ETL SIM local Y (-Z, Second Disk);Y_{SIM}^{LOC} [mm]", 100, -48., 48.);
291  meHitYlocal_[2] = ibook.book1D("EtlHitYlocalZposD1",
292  "ETL SIM local Y (+Z, Single(topo1D)/First(topo2D) disk);Y_{SIM}^{LOC} [mm]",
293  100,
294  -48.,
295  48.);
296  meHitYlocal_[3] =
297  ibook.book1D("EtlHitYlocalZposD2", "ETL SIM local Y (+Z, Second disk);Y_{SIM}^{LOC} [mm]", 100, -48., 48.);
298  meHitZlocal_[0] = ibook.book1D("EtlHitZlocalZnegD1",
299  "ETL SIM local Z (-Z, Single(topo1D)/First(topo2D) disk);Z_{SIM}^{LOC} [mm]",
300  80,
301  -0.16,
302  0.16);
303  meHitZlocal_[1] =
304  ibook.book1D("EtlHitZlocalZnegD2", "ETL SIM local Z (-Z, Second disk);Z_{SIM}^{LOC} [mm]", 80, -0.16, 0.16);
305  meHitZlocal_[2] = ibook.book1D("EtlHitZlocalZposD1",
306  "ETL SIM local Z (+Z, Single(topo1D)/First(topo2D) disk);Z_{SIM}^{LOC} [mm]",
307  80,
308  -0.16,
309  0.16);
310  meHitZlocal_[3] =
311  ibook.book1D("EtlHitZlocalZposD2", "ETL SIM local Z (+Z, Second disk);Z_{SIM}^{LOC} [mm]", 80, -0.16, 0.16);
312 
313  meOccupancy_[0] =
314  ibook.book2D("EtlOccupancyZnegD1",
315  "ETL SIM hits occupancy (-Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm];Y_{SIM} [cm]",
316  135,
317  -135.,
318  135.,
319  135,
320  -135.,
321  135.);
322  meOccupancy_[1] = ibook.book2D("EtlOccupancyZnegD2",
323  "ETL SIM hits occupancy (-Z, Second disk);X_{SIM} [cm];Y_{SIM} [cm]",
324  135,
325  -135.,
326  135.,
327  135,
328  -135.,
329  135.);
330  meOccupancy_[2] =
331  ibook.book2D("EtlOccupancyZposD1",
332  "ETL SIM hits occupancy (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm];Y_{SIM} [cm]",
333  135,
334  -135.,
335  135.,
336  135,
337  -135.,
338  135.);
339  meOccupancy_[3] = ibook.book2D("EtlOccupancyZposD2",
340  "ETL SIM hits occupancy (+Z, Second disk);X_{SIM} [cm];Y_{SIM} [cm]",
341  135,
342  -135.,
343  135.,
344  135,
345  -135.,
346  135.);
347 
348  meHitX_[0] = ibook.book1D(
349  "EtlHitXZnegD1", "ETL SIM hits X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm]", 100, -130., 130.);
350  meHitX_[1] = ibook.book1D("EtlHitXZnegD2", "ETL SIM hits X (-Z, Second disk);X_{SIM} [cm]", 100, -130., 130.);
351  meHitX_[2] = ibook.book1D(
352  "EtlHitXZposD1", "ETL SIM hits X (+Z, Single(topo1D)/First(topo2D) disk);X_{SIM} [cm]", 100, -130., 130.);
353  meHitX_[3] = ibook.book1D("EtlHitXZposD2", "ETL SIM hits X (+Z, Second disk);X_{SIM} [cm]", 100, -130., 130.);
354  meHitY_[0] = ibook.book1D(
355  "EtlHitYZnegD1", "ETL SIM hits Y (-Z, Single(topo1D)/First(topo2D) disk);Y_{SIM} [cm]", 100, -130., 130.);
356  meHitY_[1] = ibook.book1D("EtlHitYZnegD2", "ETL SIM hits Y (-Z, Second disk);Y_{SIM} [cm]", 100, -130., 130.);
357  meHitY_[2] = ibook.book1D(
358  "EtlHitYZposD1", "ETL SIM hits Y (+Z, Single(topo1D)/First(topo2D) disk);Y_{SIM} [cm]", 100, -130., 130.);
359  meHitY_[3] = ibook.book1D("EtlHitYZposD2", "ETL SIM hits Y (+Z, Second disk);Y_{SIM} [cm]", 100, -130., 130.);
360  meHitZ_[0] = ibook.book1D(
361  "EtlHitZZnegD1", "ETL SIM hits Z (-Z, Single(topo1D)/First(topo2D) disk);Z_{SIM} [cm]", 100, -302., -298.);
362  meHitZ_[1] = ibook.book1D("EtlHitZZnegD2", "ETL SIM hits Z (-Z, Second disk);Z_{SIM} [cm]", 100, -304., -300.);
363  meHitZ_[2] = ibook.book1D(
364  "EtlHitZZposD1", "ETL SIM hits Z (+Z, Single(topo1D)/First(topo2D) disk);Z_{SIM} [cm]", 100, 298., 302.);
365  meHitZ_[3] = ibook.book1D("EtlHitZZposD2", "ETL SIM hits Z (+Z, Second disk);Z_{SIM} [cm]", 100, 300., 304.);
366 
367  meHitPhi_[0] = ibook.book1D(
368  "EtlHitPhiZnegD1", "ETL SIM hits #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
369  meHitPhi_[1] =
370  ibook.book1D("EtlHitPhiZnegD2", "ETL SIM hits #phi (-Z, Second disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
371  meHitPhi_[2] = ibook.book1D(
372  "EtlHitPhiZposD1", "ETL SIM hits #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
373  meHitPhi_[3] =
374  ibook.book1D("EtlHitPhiZposD2", "ETL SIM hits #phi (+Z, Second disk);#phi_{SIM} [rad]", 100, -3.15, 3.15);
375  meHitEta_[0] = ibook.book1D(
376  "EtlHitEtaZnegD1", "ETL SIM hits #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM}", 100, -3.2, -1.56);
377  meHitEta_[1] = ibook.book1D("EtlHitEtaZnegD2", "ETL SIM hits #eta (-Z, Second disk);#eta_{SIM}", 100, -3.2, -1.56);
378  meHitEta_[2] = ibook.book1D(
379  "EtlHitEtaZposD1", "ETL SIM hits #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM}", 100, 1.56, 3.2);
380  meHitEta_[3] = ibook.book1D("EtlHitEtaZposD2", "ETL SIM hits #eta (+Z, Second disk);#eta_{SIM}", 100, 1.56, 3.2);
381 
382  meHitTvsE_[0] =
383  ibook.bookProfile("EtlHitTvsEZnegD1",
384  "ETL SIM time vs energy (-Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV];T_{SIM} [ns]",
385  50,
386  0.,
387  2.,
388  0.,
389  100.);
390  meHitTvsE_[1] = ibook.bookProfile(
391  "EtlHitTvsEZnegD2", "ETL SIM time vs energy (-Z, Second disk);E_{SIM} [MeV];T_{SIM} [ns]", 50, 0., 2., 0., 100.);
392  meHitTvsE_[2] =
393  ibook.bookProfile("EtlHitTvsEZposD1",
394  "ETL SIM time vs energy (+Z, Single(topo1D)/First(topo2D) disk);E_{SIM} [MeV];T_{SIM} [ns]",
395  50,
396  0.,
397  2.,
398  0.,
399  100.);
400  meHitTvsE_[3] = ibook.bookProfile(
401  "EtlHitTvsEZposD2", "ETL SIM time vs energy (+Z, Second disk);E_{SIM} [MeV];T_{SIM} [ns]", 50, 0., 2., 0., 100.);
402  meHitEvsPhi_[0] =
403  ibook.bookProfile("EtlHitEvsPhiZnegD1",
404  "ETL SIM energy vs #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
405  50,
406  -3.15,
407  3.15,
408  0.,
409  100.);
410  meHitEvsPhi_[1] = ibook.bookProfile("EtlHitEvsPhiZnegD2",
411  "ETL SIM energy vs #phi (-Z, Second disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
412  50,
413  -3.15,
414  3.15,
415  0.,
416  100.);
417  meHitEvsPhi_[2] =
418  ibook.bookProfile("EtlHitEvsPhiZposD1",
419  "ETL SIM energy vs #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
420  50,
421  -3.15,
422  3.15,
423  0.,
424  100.);
425  meHitEvsPhi_[3] = ibook.bookProfile("EtlHitEvsPhiZposD2",
426  "ETL SIM energy vs #phi (+Z, Second disk);#phi_{SIM} [rad];E_{SIM} [MeV]",
427  50,
428  -3.15,
429  3.15,
430  0.,
431  100.);
432  meHitEvsEta_[0] =
433  ibook.bookProfile("EtlHitEvsEtaZnegD1",
434  "ETL SIM energy vs #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};E_{SIM} [MeV]",
435  50,
436  -3.2,
437  -1.56,
438  0.,
439  100.);
440  meHitEvsEta_[1] = ibook.bookProfile("EtlHitEvsEtaZnegD2",
441  "ETL SIM energy vs #eta (-Z, Second disk);#eta_{SIM};E_{SIM} [MeV]",
442  50,
443  -3.2,
444  -1.56,
445  0.,
446  100.);
447  meHitEvsEta_[2] =
448  ibook.bookProfile("EtlHitEvsEtaZposD1",
449  "ETL SIM energy vs #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};E_{SIM} [MeV]",
450  50,
451  1.56,
452  3.2,
453  0.,
454  100.);
455  meHitEvsEta_[3] = ibook.bookProfile("EtlHitEvsEtaZposD2",
456  "ETL SIM energy vs #eta (+Z, Second disk);#eta_{SIM};E_{SIM} [MeV]",
457  50,
458  1.56,
459  3.2,
460  0.,
461  100.);
462  meHitTvsPhi_[0] =
463  ibook.bookProfile("EtlHitTvsPhiZnegD1",
464  "ETL SIM time vs #phi (-Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];T_{SIM} [ns]",
465  50,
466  -3.15,
467  3.15,
468  0.,
469  100.);
470  meHitTvsPhi_[1] = ibook.bookProfile("EtlHitTvsPhiZnegD2",
471  "ETL SIM time vs #phi (-Z, Second disk);#phi_{SIM} [rad];T_{SIM} [ns]",
472  50,
473  -3.15,
474  3.15,
475  0.,
476  100.);
477  meHitTvsPhi_[2] =
478  ibook.bookProfile("EtlHitTvsPhiZposD1",
479  "ETL SIM time vs #phi (+Z, Single(topo1D)/First(topo2D) disk);#phi_{SIM} [rad];T_{SIM} [ns]",
480  50,
481  -3.15,
482  3.15,
483  0.,
484  100.);
485  meHitTvsPhi_[3] = ibook.bookProfile("EtlHitTvsPhiZposD2",
486  "ETL SIM time vs #phi (+Z, Second disk);#phi_{SIM} [rad];T_{SIM} [ns]",
487  50,
488  -3.15,
489  3.15,
490  0.,
491  100.);
492  meHitTvsEta_[0] =
493  ibook.bookProfile("EtlHitTvsEtaZnegD1",
494  "ETL SIM time vs #eta (-Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};T_{SIM} [ns]",
495  50,
496  -3.2,
497  -1.56,
498  0.,
499  100.);
500  meHitTvsEta_[1] = ibook.bookProfile(
501  "EtlHitTvsEtaZnegD2", "ETL SIM time vs #eta (-Z, Second disk);#eta_{SIM};T_{SIM} [ns]", 50, -3.2, -1.56, 0., 100.);
502  meHitTvsEta_[2] =
503  ibook.bookProfile("EtlHitTvsEtaZposD1",
504  "ETL SIM time vs #eta (+Z, Single(topo1D)/First(topo2D) disk);#eta_{SIM};T_{SIM} [ns]",
505  50,
506  1.56,
507  3.2,
508  0.,
509  100.);
510  meHitTvsEta_[3] = ibook.bookProfile(
511  "EtlHitTvsEtaZposD2", "ETL SIM time vs #eta (+Z, Second disk);#eta_{SIM};T_{SIM} [ns]", 50, 1.56, 3.2, 0., 100.);
512 }
513 
514 // ------------ method fills 'descriptions' with the allowed parameters for the module ------------
517 
518  desc.add<std::string>("folder", "MTD/ETL/SimHits");
519  desc.add<edm::InputTag>("inputTag", edm::InputTag("mix", "g4SimHitsFastTimerHitsEndcap"));
520  desc.add<double>("hitMinimumEnergy2Dis", 0.001); // [MeV]
521 
522  descriptions.add("etlSimHitsValid", desc);
523 }
524 
size
Write out results.
T getParameter(std::string const &) const
Definition: ParameterSet.h:307
edm::ESGetToken< MTDGeometry, MTDDigiGeometryRecord > mtdgeoToken_
MonitorElement * meNhits_[4]
std::string folder_
MonitorElement * meHitYlocal_[4]
virtual void setCurrentFolder(std::string const &fullpath)
Definition: DQMStore.cc:36
edm::EDGetTokenT< CrossingFrame< PSimHit > > etlSimHitsToken_
Definition: MTDHit.h:4
Definition: weight.py:1
MonitorElement * meOccupancy_[4]
int zside(DetId const &)
MonitorElement * meHitY_[4]
MonitorElement * meHitTvsEta_[4]
void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
constexpr NumType convertUnitsTo(double desiredUnits, NumType val)
Definition: GeantUnits.h:73
void Fill(long long x)
MonitorElement * meHitXlocal_[4]
int iEvent
Definition: GenABIO.cc:224
EtlSimHitsValidation(const edm::ParameterSet &)
MonitorElement * bookProfile(TString const &name, TString const &title, int nchX, double lowX, double highX, int, double lowY, double highY, char const *option="s", FUNC onbooking=NOOP())
Definition: DQMStore.h:408
MonitorElement * meHitTvsPhi_[4]
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:16
MonitorElement * meHitX_[4]
MonitorElement * meHitEvsEta_[4]
MonitorElement * meHitEta_[4]
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:49
MonitorElement * meHitTime_[4]
Definition: DetId.h:17
MonitorElement * meHitPhi_[4]
MonitorElement * meHitTvsE_[4]
constexpr NumType convertMmToCm(NumType millimeters)
Definition: angle_units.h:44
constexpr uint32_t rawId() const
get the raw id
Definition: DetId.h:57
MonitorElement * book2D(TString const &name, TString const &title, int nchX, double lowX, double highX, int nchY, double lowY, double highY, FUNC onbooking=NOOP())
Definition: DQMStore.h:221
void analyze(const edm::Event &, const edm::EventSetup &) override
void add(std::string const &label, ParameterSetDescription const &psetDescription)
static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
Detector identifier class for the Endcap Timing Layer.
Definition: ETLDetId.h:16
HLT enums.
MonitorElement * meHitZlocal_[4]
ESTransientHandle< T > getTransientHandle(const ESGetToken< T, R > &iToken) const
Definition: EventSetup.h:141
Log< level::Warning, false > LogWarning
MonitorElement * meNtrkPerCell_[4]
MonitorElement * meHitEnergy_[4]
auto makeValid(const U &iOtherHandleType) noexcept(false)
Definition: ValidHandle.h:52
MonitorElement * book1D(TString const &name, TString const &title, int const nchX, double const lowX, double const highX, FUNC onbooking=NOOP())
Definition: DQMStore.h:98
const std::string folder_
MonitorElement * meHitEvsPhi_[4]
Definition: Run.h:45
edm::ESGetToken< MTDTopology, MTDTopologyRcd > mtdtopoToken_
#define LogDebug(id)
MonitorElement * meHitZ_[4]