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CalibrationSummaryFactory.cc
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5 #include <iostream>
6 #include <sstream>
7 
8 using namespace sistrip;
9 
10 // -----------------------------------------------------------------------------
11 //
13  CalibrationAnalysis* anal = dynamic_cast<CalibrationAnalysis*>(iter->second);
14  if (!anal) {
15  return;
16  }
17 
18  std::vector<float> temp(128, 1. * sistrip::invalid_);
19  std::vector<std::vector<float> > amplitude(2, temp);
20  std::vector<std::vector<float> > baseline(2, temp);
21  std::vector<std::vector<float> > riseTime(2, temp);
22  std::vector<std::vector<float> > turnOn(2, temp);
23  std::vector<std::vector<float> > peakTime(2, temp);
24  std::vector<std::vector<float> > undershoot(2, temp);
25  std::vector<std::vector<float> > tail(2, temp);
26  std::vector<std::vector<float> > decayTime(2, temp);
27  std::vector<std::vector<float> > smearing(2, temp);
28  std::vector<std::vector<float> > chi2(2, temp);
29 
30  std::vector<std::vector<float> > value(2, temp);
31 
32  amplitude[0] = anal->amplitude()[0];
33  amplitude[1] = anal->amplitude()[1];
34  baseline[0] = anal->baseline()[0];
35  baseline[1] = anal->baseline()[1];
36  tail[0] = anal->tail()[0];
37  tail[1] = anal->tail()[1];
38  riseTime[0] = anal->riseTime()[0];
39  riseTime[1] = anal->riseTime()[1];
40  decayTime[0] = anal->decayTime()[0];
41  decayTime[1] = anal->decayTime()[1];
42  peakTime[0] = anal->peakTime()[0];
43  peakTime[1] = anal->peakTime()[1];
44  turnOn[0] = anal->turnOn()[0];
45  turnOn[1] = anal->turnOn()[1];
46  undershoot[0] = anal->undershoot()[0];
47  undershoot[1] = anal->undershoot()[1];
48  smearing[0] = anal->smearing()[0];
49  smearing[1] = anal->smearing()[1];
50  chi2[0] = anal->chi2()[0];
51  chi2[1] = anal->chi2()[1];
52 
53  SiStripFecKey lldKey = SiStripFecKey(iter->first);
54 
55  uint32_t key1 = SiStripFecKey(lldKey.fecCrate(),
56  lldKey.fecSlot(),
57  lldKey.fecRing(),
58  lldKey.ccuAddr(),
59  lldKey.ccuChan(),
60  lldKey.lldChan(),
61  lldKey.i2cAddr(lldKey.lldChan(), true))
62  .key();
63 
64  uint32_t key2 = SiStripFecKey(lldKey.fecCrate(),
65  lldKey.fecSlot(),
66  lldKey.fecRing(),
67  lldKey.ccuAddr(),
68  lldKey.ccuChan(),
69  lldKey.lldChan(),
70  lldKey.i2cAddr(lldKey.lldChan(), false))
71  .key();
72 
73  bool all_strips = false;
75  all_strips = true;
76  uint16_t bins = amplitude[amplitude[0].size() < amplitude[1].size() ? 1 : 0].size();
77  for (uint16_t i = 0; i < bins; i++) {
78  value[0][i] = amplitude[0][i];
79  value[1][i] = amplitude[1][i];
80  }
81  } else if (mon_ == sistrip::CALIBRATION_BASELINE_ALL_STRIPS) {
82  all_strips = true;
83  uint16_t bins = baseline[baseline[0].size() < baseline[1].size() ? 1 : 0].size();
84  for (uint16_t i = 0; i < bins; i++) {
85  value[0][i] = baseline[0][i];
86  value[1][i] = baseline[1][i];
87  }
88  } else if (mon_ == sistrip::CALIBRATION_TURNON_ALL_STRIPS) {
89  all_strips = true;
90  uint16_t bins = turnOn[turnOn[0].size() < turnOn[1].size() ? 1 : 0].size();
91  for (uint16_t i = 0; i < bins; i++) {
92  value[0][i] = turnOn[0][i];
93  value[1][i] = turnOn[1][i];
94  }
95  } else if (mon_ == sistrip::CALIBRATION_RISETIME_ALL_STRIPS) {
96  all_strips = true;
97  uint16_t bins = riseTime[riseTime[0].size() < riseTime[1].size() ? 1 : 0].size();
98  for (uint16_t i = 0; i < bins; i++) {
99  value[0][i] = riseTime[0][i];
100  value[1][i] = riseTime[1][i];
101  }
102  } else if (mon_ == sistrip::CALIBRATION_DECAYTIME_ALL_STRIPS) {
103  all_strips = true;
104  uint16_t bins = decayTime[decayTime[0].size() < decayTime[1].size() ? 1 : 0].size();
105  for (uint16_t i = 0; i < bins; i++) {
106  value[0][i] = decayTime[0][i];
107  value[1][i] = decayTime[1][i];
108  }
109  } else if (mon_ == sistrip::CALIBRATION_PEAKTIME_ALL_STRIPS) {
110  all_strips = true;
111  uint16_t bins = peakTime[peakTime[0].size() < peakTime[1].size() ? 1 : 0].size();
112  for (uint16_t i = 0; i < bins; i++) {
113  value[0][i] = peakTime[0][i];
114  value[1][i] = peakTime[1][i];
115  }
116  } else if (mon_ == sistrip::CALIBRATION_UNDERSHOOT_ALL_STRIPS) {
117  all_strips = true;
118  uint16_t bins = undershoot[undershoot[0].size() < undershoot[1].size() ? 1 : 0].size();
119  for (uint16_t i = 0; i < bins; i++) {
120  value[0][i] = undershoot[0][i];
121  value[1][i] = undershoot[1][i];
122  }
123  } else if (mon_ == sistrip::CALIBRATION_TAIL_ALL_STRIPS) {
124  all_strips = true;
125  uint16_t bins = tail[tail[0].size() < tail[1].size() ? 1 : 0].size();
126  for (uint16_t i = 0; i < bins; i++) {
127  value[0][i] = tail[0][i];
128  value[1][i] = tail[1][i];
129  }
130  } else if (mon_ == sistrip::CALIBRATION_SMEARING_ALL_STRIPS) {
131  all_strips = true;
132  uint16_t bins = smearing[smearing[0].size() < smearing[1].size() ? 1 : 0].size();
133  for (uint16_t i = 0; i < bins; i++) {
134  value[0][i] = smearing[0][i];
135  value[1][i] = smearing[1][i];
136  }
137  } else if (mon_ == sistrip::CALIBRATION_CHI2_ALL_STRIPS) {
138  all_strips = true;
139  uint16_t bins = chi2[chi2[0].size() < chi2[1].size() ? 1 : 0].size();
140  for (uint16_t i = 0; i < bins; i++) {
141  value[0][i] = chi2[0][i];
142  value[1][i] = chi2[1][i];
143  }
144  }
146  else if (mon_ == sistrip::CALIBRATION_AMPLITUDE_MEAN) {
147  value[0][0] = anal->amplitudeMean()[0];
148  value[1][0] = anal->amplitudeMean()[1];
149  } else if (mon_ == sistrip::CALIBRATION_BASELINE_MEAN) {
150  value[0][0] = anal->baselineMean()[0];
151  value[1][0] = anal->baselineMean()[1];
152  } else if (mon_ == sistrip::CALIBRATION_TURNON_MEAN) {
153  value[0][0] = anal->turnOnMean()[0];
154  value[1][0] = anal->turnOnMean()[1];
155  } else if (mon_ == sistrip::CALIBRATION_RISETIME_MEAN) {
156  value[0][0] = anal->riseTimeMean()[0];
157  value[1][0] = anal->riseTimeMean()[1];
158  } else if (mon_ == sistrip::CALIBRATION_DECAYTIME_MEAN) {
159  value[0][0] = anal->decayTimeMean()[0];
160  value[1][0] = anal->decayTimeMean()[1];
161  } else if (mon_ == sistrip::CALIBRATION_PEAKTIME_MEAN) {
162  value[0][0] = anal->peakTimeMean()[0];
163  value[1][0] = anal->peakTimeMean()[1];
164  } else if (mon_ == sistrip::CALIBRATION_UNDERSHOOT_MEAN) {
165  value[0][0] = anal->undershootMean()[0];
166  value[1][0] = anal->undershootMean()[1];
167  } else if (mon_ == sistrip::CALIBRATION_TAIL_MEAN) {
168  value[0][0] = anal->tailMean()[0];
169  value[1][0] = anal->tailMean()[1];
170  } else if (mon_ == sistrip::CALIBRATION_SMEARING_MEAN) {
171  value[0][0] = anal->smearingMean()[0];
172  value[1][0] = anal->smearingMean()[1];
173  } else if (mon_ == sistrip::CALIBRATION_CHI2_MEAN) {
174  value[0][0] = anal->chi2Mean()[0];
175  value[1][0] = anal->chi2Mean()[1];
176  }
178  else if (mon_ == sistrip::CALIBRATION_AMPLITUDE_MIN) {
179  value[0][0] = anal->amplitudeMin()[0];
180  value[1][0] = anal->amplitudeMin()[1];
181  } else if (mon_ == sistrip::CALIBRATION_BASELINE_MIN) {
182  value[0][0] = anal->baselineMin()[0];
183  value[1][0] = anal->baselineMin()[1];
184  } else if (mon_ == sistrip::CALIBRATION_TURNON_MIN) {
185  value[0][0] = anal->turnOnMin()[0];
186  value[1][0] = anal->turnOnMin()[1];
187  } else if (mon_ == sistrip::CALIBRATION_RISETIME_MIN) {
188  value[0][0] = anal->riseTimeMin()[0];
189  value[1][0] = anal->riseTimeMin()[1];
190  } else if (mon_ == sistrip::CALIBRATION_DECAYTIME_MIN) {
191  value[0][0] = anal->decayTimeMin()[0];
192  value[1][0] = anal->decayTimeMin()[1];
193  } else if (mon_ == sistrip::CALIBRATION_PEAKTIME_MIN) {
194  value[0][0] = anal->peakTimeMin()[0];
195  value[1][0] = anal->peakTimeMin()[1];
196  } else if (mon_ == sistrip::CALIBRATION_UNDERSHOOT_MIN) {
197  value[0][0] = anal->undershootMin()[0];
198  value[1][0] = anal->undershootMin()[1];
199  } else if (mon_ == sistrip::CALIBRATION_TAIL_MIN) {
200  value[0][0] = anal->tailMin()[0];
201  value[1][0] = anal->tailMin()[1];
202  } else if (mon_ == sistrip::CALIBRATION_SMEARING_MIN) {
203  value[0][0] = anal->smearingMin()[0];
204  value[1][0] = anal->smearingMin()[1];
205  } else if (mon_ == sistrip::CALIBRATION_CHI2_MIN) {
206  value[0][0] = anal->chi2Min()[0];
207  value[1][0] = anal->chi2Min()[1];
208  }
210  else if (mon_ == sistrip::CALIBRATION_AMPLITUDE_MAX) {
211  value[0][0] = anal->amplitudeMax()[0];
212  value[1][0] = anal->amplitudeMax()[1];
213  } else if (mon_ == sistrip::CALIBRATION_BASELINE_MAX) {
214  value[0][0] = anal->baselineMax()[0];
215  value[1][0] = anal->baselineMax()[1];
216  } else if (mon_ == sistrip::CALIBRATION_TURNON_MAX) {
217  value[0][0] = anal->turnOnMax()[0];
218  value[1][0] = anal->turnOnMax()[1];
219  } else if (mon_ == sistrip::CALIBRATION_RISETIME_MAX) {
220  value[0][0] = anal->riseTimeMax()[0];
221  value[1][0] = anal->riseTimeMax()[1];
222  } else if (mon_ == sistrip::CALIBRATION_DECAYTIME_MAX) {
223  value[0][0] = anal->decayTimeMax()[0];
224  value[1][0] = anal->decayTimeMax()[1];
225  } else if (mon_ == sistrip::CALIBRATION_PEAKTIME_MAX) {
226  value[0][0] = anal->peakTimeMax()[0];
227  value[1][0] = anal->peakTimeMax()[1];
228  } else if (mon_ == sistrip::CALIBRATION_UNDERSHOOT_MAX) {
229  value[0][0] = anal->undershootMax()[0];
230  value[1][0] = anal->undershootMax()[1];
231  } else if (mon_ == sistrip::CALIBRATION_TAIL_MAX) {
232  value[0][0] = anal->tailMax()[0];
233  value[1][0] = anal->tailMax()[1];
234  } else if (mon_ == sistrip::CALIBRATION_SMEARING_MAX) {
235  value[0][0] = anal->smearingMax()[0];
236  value[1][0] = anal->smearingMax()[1];
237  } else if (mon_ == sistrip::CALIBRATION_CHI2_MAX) {
238  value[0][0] = anal->chi2Max()[0];
239  value[1][0] = anal->chi2Max()[1];
240  }
242  else if (mon_ == sistrip::CALIBRATION_AMPLITUDE_SPREAD) {
243  value[0][0] = anal->amplitudeSpread()[0];
244  value[1][0] = anal->amplitudeSpread()[1];
245  } else if (mon_ == sistrip::CALIBRATION_BASELINE_SPREAD) {
246  value[0][0] = anal->baselineSpread()[0];
247  value[1][0] = anal->baselineSpread()[1];
248  } else if (mon_ == sistrip::CALIBRATION_TURNON_SPREAD) {
249  value[0][0] = anal->turnOnSpread()[0];
250  value[1][0] = anal->turnOnSpread()[1];
251  } else if (mon_ == sistrip::CALIBRATION_RISETIME_SPREAD) {
252  value[0][0] = anal->riseTimeSpread()[0];
253  value[1][0] = anal->riseTimeSpread()[1];
254  } else if (mon_ == sistrip::CALIBRATION_DECAYTIME_SPREAD) {
255  value[0][0] = anal->decayTimeSpread()[0];
256  value[1][0] = anal->decayTimeSpread()[1];
257  } else if (mon_ == sistrip::CALIBRATION_PEAKTIME_SPREAD) {
258  value[0][0] = anal->peakTimeSpread()[0];
259  value[1][0] = anal->peakTimeSpread()[1];
260  } else if (mon_ == sistrip::CALIBRATION_UNDERSHOOT_SPREAD) {
261  value[0][0] = anal->undershootSpread()[0];
262  value[1][0] = anal->undershootSpread()[1];
263  } else if (mon_ == sistrip::CALIBRATION_TAIL_SPREAD) {
264  value[0][0] = anal->tailSpread()[0];
265  value[1][0] = anal->tailSpread()[1];
266  } else if (mon_ == sistrip::CALIBRATION_SMEARING_SPREAD) {
267  value[0][0] = anal->smearingSpread()[0];
268  value[1][0] = anal->smearingSpread()[1];
269  } else if (mon_ == sistrip::CALIBRATION_CHI2_SPREAD) {
270  value[0][0] = anal->chi2Spread()[0];
271  value[1][0] = anal->chi2Spread()[1];
272  } else {
273  edm::LogWarning(mlSummaryPlots_) << "[SummaryPlotFactory::" << __func__ << "]"
274  << " Unexpected monitorable: "
276  return;
277  }
278 
279  if (!all_strips) {
282 
285  } else {
286  for (uint16_t istr = 0; istr < value[0].size(); istr++)
289 
290  for (uint16_t istr = 0; istr < value[1].size(); istr++)
293  }
294 
295  format();
296 }
297 
298 //------------------------------------------------------------------------------
299 //
301  // Histogram formatting
305  generator_->axisLabel("Amplitude (ADC)");
306 
310  generator_->axisLabel("Baseline (ADC)");
311 
315  generator_->axisLabel("Turn-On (ns)");
316 
320  generator_->axisLabel("Tail (%)");
321 
325  generator_->axisLabel("Rise Time (ns)");
326 
330  generator_->axisLabel("Peak Time (ns)");
331 
335  generator_->axisLabel("Decay Time (ns)");
336 
340  generator_->axisLabel("Smearing (ns)");
341 
345  generator_->axisLabel("Chi2/ndf");
346 
350  generator_->axisLabel("Undershoot (%)");
351 
352  else {
353  edm::LogWarning(mlSummaryPlots_) << "[SummaryPlotFactory::" << __func__ << "]"
354  << " Unexpected SummaryHisto value:"
356  }
357 }
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