source: trunk/FACT++/src/feedback.cc@ 17417

Last change on this file since 17417 was 17234, checked in by tbretz, 11 years ago
So far the assumption was that the precise one is the DAC, but (most probably) because some current is lost into the OpAMP, the really precise device is the ADC. Consequently, the inverse calibration factor applies to I9 and not to I8.
File size: 42.1 KB
Line 
1#include <valarray>
2#include <algorithm>
3
4#include "Dim.h"
5#include "Event.h"
6#include "Shell.h"
7#include "StateMachineDim.h"
8#include "Connection.h"
9#include "Configuration.h"
10#include "Console.h"
11#include "externals/PixelMap.h"
12#include "externals/Interpolator2D.h"
13
14#include "tools.h"
15
16#include "LocalControl.h"
17
18#include "HeadersFSC.h"
19#include "HeadersBIAS.h"
20#include "HeadersFeedback.h"
21
22#include "DimState.h"
23#include "DimDescriptionService.h"
24
25using namespace std;
26
27// ------------------------------------------------------------------------
28
29class StateMachineFeedback : public StateMachineDim
30{
31private:
32 PixelMap fMap;
33
34 bool fIsVerbose;
35
36 DimVersion fDim;
37
38 DimDescribedState fDimFSC;
39 DimDescribedState fDimBias;
40
41 DimDescribedService fDimCalibration;
42 DimDescribedService fDimCalibration2;
43 DimDescribedService fDimCalibrationR8;
44 DimDescribedService fDimCurrents;
45 DimDescribedService fDimOffsets;
46
47 vector<float> fCalibCurrentMes[6]; // Measured calibration current at six different levels
48 vector<float> fCalibVoltage[6]; // Corresponding voltage as reported by biasctrl
49
50 vector<int64_t> fCurrentsAvg;
51 vector<int64_t> fCurrentsRms;
52
53 vector<float> fVoltGapd; // Nominal breakdown voltage + 1.1V
54 vector<float> fBiasVolt; // Output voltage as reported by bias crate (voltage between R10 and R8)
55 vector<float> fBiasR9; //
56 vector<uint16_t> fBiasDac; // Dac value corresponding to the voltage setting
57
58 vector<float> fCalibration;
59 vector<float> fCalibDeltaI;
60 vector<float> fCalibR8;
61
62 int64_t fCursorCur;
63
64 Time fTimeCalib;
65 Time fTimeTemp;
66
67 double fUserOffset;
68 vector<double> fTempOffset;
69 float fTempOffsetAvg;
70 float fTempOffsetRms;
71 double fTempCoefficient;
72 double fTemp;
73
74 vector<double> fVoltOffset;
75
76 uint16_t fCurrentRequestInterval;
77 uint16_t fNumCalibIgnore;
78 uint16_t fNumCalibRequests;
79 uint16_t fCalibStep;
80
81 // ============================= Handle Services ========================
82
83 int HandleBiasStateChange()
84 {
85 if (fDimBias.state()==BIAS::State::kVoltageOn && GetCurrentState()==Feedback::State::kCalibrating)
86 {
87 Dim::SendCommandNB("BIAS_CONTROL/REQUEST_STATUS");
88 Info("Starting calibration step "+to_string(fCalibStep));
89 }
90
91 if (fDimBias.state()==BIAS::State::kVoltageOff && GetCurrentState()==Feedback::State::kInProgress)
92 return Feedback::State::kCalibrated;
93
94 return GetCurrentState();
95 }
96 // ============================= Handle Services ========================
97
98 bool CheckEventSize(size_t has, const char *name, size_t size)
99 {
100 if (has==size)
101 return true;
102
103 // Disconnected
104 if (has==0)
105 return false;
106
107 ostringstream msg;
108 msg << name << " - Received event has " << has << " bytes, but expected " << size << ".";
109 Fatal(msg);
110 return false;
111 }
112
113 int HandleBiasNom(const EventImp &evt)
114 {
115 if (evt.GetSize()>=416*sizeof(float))
116 {
117 fVoltGapd.assign(evt.Ptr<float>(), evt.Ptr<float>()+416);
118 fBiasR9.assign(evt.Ptr<float>()+2*416, evt.Ptr<float>()+3*416);
119 Info("Nominal bias voltages and calibration resistor received.");
120 }
121
122 return GetCurrentState();
123 }
124
125 int HandleBiasVoltage(const EventImp &evt)
126 {
127 if (evt.GetSize()>=416*sizeof(float))
128 fBiasVolt.assign(evt.Ptr<float>(), evt.Ptr<float>()+416);
129 return GetCurrentState();
130 }
131
132 int HandleBiasDac(const EventImp &evt)
133 {
134 if (evt.GetSize()>=416*sizeof(uint16_t))
135 fBiasDac.assign(evt.Ptr<uint16_t>(), evt.Ptr<uint16_t>()+416);
136 return GetCurrentState();
137 }
138
139 int HandleCameraTemp(const EventImp &evt)
140 {
141 if (!CheckEventSize(evt.GetSize(), "HandleCameraTemp", 323*sizeof(float)))
142 {
143 fTimeTemp = Time(Time::none);
144 return GetCurrentState();
145 }
146
147 //fTempOffset = (avgt-25)*0.0561765; // [V] From Hamamatsu datasheet
148 //fTempOffset = (avgt-25)*0.05678; // [V] From Hamamatsu datasheet plus our own measurement (gein vs. temperature)
149
150 const float *ptr = evt.Ptr<float>(4);
151
152 fTimeTemp = evt.GetTime();
153 fTemp = evt.Get<float>(321*4);
154
155 fTempOffsetAvg = (fTemp-25)*fTempCoefficient;
156 fTempOffsetRms = evt.Get<float>(322*4)*fTempCoefficient;
157
158 fTempOffset.resize(320);
159 for (int i=0; i<320; i++)
160 fTempOffset[i] = (ptr[i]-25)*fTempCoefficient;
161
162 return GetCurrentState();
163 }
164
165 pair<vector<float>, vector<float>> AverageCurrents(const int16_t *ptr, int n)
166 {
167 if (fCursorCur++>=0)
168 {
169 for (int i=0; i<BIAS::kNumChannels; i++)
170 {
171 fCurrentsAvg[i] += ptr[i];
172 fCurrentsRms[i] += ptr[i]*ptr[i];
173 }
174 }
175
176 if (fCursorCur<n)
177 return make_pair(vector<float>(), vector<float>());
178
179 const double conv = 5e-3/4096;
180
181 vector<float> rms(BIAS::kNumChannels);
182 vector<float> avg(BIAS::kNumChannels);
183 for (int i=0; i<BIAS::kNumChannels; i++)
184 {
185 avg[i] = double(fCurrentsAvg[i])/fCursorCur * conv;
186 rms[i] = double(fCurrentsRms[i])/fCursorCur * conv * conv;
187 rms[i] -= avg[i]*avg[i];
188 rms[i] = rms[i]<0 ? 0 : sqrt(rms[i]);
189 }
190
191 return make_pair(avg, rms);
192 }
193
194 int HandleCalibration(const EventImp &evt)
195 {
196 if (fDimBias.state()!=BIAS::State::kVoltageOn)
197 return GetCurrentState();
198
199 const uint16_t dac = 256+512*fCalibStep; // Command value
200
201 // Only the channels which are no spare channels are ramped
202 if (std::count(fBiasDac.begin(), fBiasDac.end(), dac)!=320)
203 return GetCurrentState();
204
205 const auto rc = AverageCurrents(evt.Ptr<int16_t>(), fNumCalibRequests);
206 if (rc.first.size()==0)
207 {
208 Dim::SendCommandNB("BIAS_CONTROL/REQUEST_STATUS");
209 return GetCurrentState();
210 }
211
212 const vector<float> &avg = rc.first;
213 const vector<float> &rms = rc.second;
214
215 // Current through resistor R8
216 fCalibCurrentMes[fCalibStep] = avg; // [A]
217 fCalibVoltage[fCalibStep] = fBiasVolt; // [V]
218
219 // ------------------------- Update calibration data --------------------
220
221 struct cal_data
222 {
223 uint32_t dac;
224 float U[416];
225 float Iavg[416];
226 float Irms[416];
227
228 cal_data() { memset(this, 0, sizeof(cal_data)); }
229 } __attribute__((__packed__));
230
231 cal_data cal;
232 cal.dac = dac;
233 memcpy(cal.U, fBiasVolt.data(), 416*sizeof(float));
234 memcpy(cal.Iavg, avg.data(), 416*sizeof(float));
235 memcpy(cal.Irms, rms.data(), 416*sizeof(float));
236
237 fDimCalibration2.setData(cal);
238 fDimCalibration2.Update(fTimeCalib);
239
240 // -------------------- Start next calibration steo ---------------------
241
242 if (++fCalibStep<6)
243 {
244 fCursorCur = -fNumCalibIgnore;
245 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
246 fCurrentsRms.assign(BIAS::kNumChannels, 0);
247
248 Dim::SendCommandNB("BIAS_CONTROL/SET_GLOBAL_DAC", uint32_t(256+512*fCalibStep));
249
250 return GetCurrentState();
251 }
252
253 // --------------- Calculate old style calibration ----------------------
254
255 fCalibration.resize(BIAS::kNumChannels*4);
256
257 float *pavg = fCalibration.data();
258 float *prms = fCalibration.data()+BIAS::kNumChannels;
259 float *pres = fCalibration.data()+BIAS::kNumChannels*2;
260 float *pUmes = fCalibration.data()+BIAS::kNumChannels*3;
261
262 for (int i=0; i<BIAS::kNumChannels; i++)
263 {
264 const double I = fCalibCurrentMes[5][i]; // [A]
265 const double U = fBiasVolt[i]; // [V]
266
267 pavg[i] = I*1e6; // [uA]
268 prms[i] = rms[i]*1e6; // [uA]
269 pres[i] = U/I; // [Ohm]
270 pUmes[i] = U; // [V]
271 }
272
273 fDimCalibration.setData(fCalibration);
274 fDimCalibration.Update(fTimeCalib);
275
276 // -------------------- New style calibration --------------------------
277
278 fCalibDeltaI.resize(BIAS::kNumChannels);
279 fCalibR8.resize(BIAS::kNumChannels);
280
281 // Linear regression of the values at 256+512*N for N={ 3, 4, 5 }
282 for (int i=0; i<BIAS::kNumChannels; i++)
283 {
284 // x: Idac
285 // y: Iadc
286
287 double x = 0;
288 double y = 0;
289 double xx = 0;
290 double xy = 0;
291
292 const int beg = 3;
293 const int end = 5;
294 const int len = end-beg+1;
295
296 for (int j=beg; j<=end; j++)
297 {
298 const double Idac = (256+512*j)*1e-3/4096;
299
300 x += Idac;
301 xx += Idac*Idac;
302 y += fCalibCurrentMes[j][i];
303 xy += fCalibCurrentMes[j][i]*Idac;
304 }
305
306 const double m1 = xy - x*y / len;
307 const double m2 = xx - x*x / len;
308
309 const double m = m2==0 ? 0 : m1/m2;
310
311 const double t = (y - m*x) / len;
312
313 fCalibDeltaI[i] = t; // [A]
314 fCalibR8[i] = 100/m; // [Ohm]
315 }
316
317 vector<float> v;
318 v.reserve(BIAS::kNumChannels*2);
319 v.insert(v.end(), fCalibDeltaI.begin(), fCalibDeltaI.end());
320 v.insert(v.end(), fCalibR8.begin(), fCalibR8.end());
321
322 fDimCalibrationR8.setData(v);
323 fDimCalibrationR8.Update(fTimeCalib);
324
325 // ---------------------------------------------------------------------
326
327 Info("Calibration successfully done.");
328 Dim::SendCommandNB("BIAS_CONTROL/SET_ZERO_VOLTAGE");
329
330 return Feedback::State::kCalibrated;
331 }
332
333 int HandleBiasCurrent(const EventImp &evt)
334 {
335 if (!CheckEventSize(evt.GetSize(), "HandleBiasCurrent", BIAS::kNumChannels*sizeof(uint16_t)))
336 return Feedback::State::kConnected;
337
338 if (GetCurrentState()<Feedback::State::kCalibrating)
339 return GetCurrentState();
340
341 // ------------------------------- HandleCalibration -----------------------------------
342 if (GetCurrentState()==Feedback::State::kCalibrating)
343 return HandleCalibration(evt);
344
345 // ---------------------- Calibrated, WaitingForData, InProgress -----------------------
346
347 // We are waiting but no valid temperature yet, go on waiting
348 if (GetCurrentState()==Feedback::State::kWaitingForData &&
349 (!fTimeTemp.IsValid() || Time()-fTimeTemp>boost::posix_time::minutes(5)))
350 return GetCurrentState();
351
352 // We are already in progress but no valid temperature update anymore
353 if (GetCurrentState()==Feedback::State::kInProgress &&
354 (!fTimeTemp.IsValid() || Time()-fTimeTemp>boost::posix_time::minutes(5)))
355 {
356 Warn("Current control in progress, but last received temperature older than 5min... switching voltage off.");
357 Dim::SendCommandNB("BIAS_CONTROL/SET_ZERO_VOLTAGE");
358 return Feedback::State::kCalibrated;
359 }
360
361 // ---------------------- Calibrated, WaitingForData, InProgress -----------------------
362
363 const int Navg = fDimBias.state()!=BIAS::State::kVoltageOn ? 1 : 3;
364
365 const vector<float> &Imes = AverageCurrents(evt.Ptr<int16_t>(), Navg).first;
366 if (Imes.size()==0)
367 return GetCurrentState();
368
369 fCurrentsAvg.assign(416, 0);
370 fCurrentsRms.assign(416, 0);
371 fCursorCur = 0;
372
373 // -------------------------------------------------------------------------------------
374
375 // Nominal overvoltage (w.r.t. the bias setup values)
376 const double overvoltage = GetCurrentState()<Feedback::State::kWaitingForData ? 0 : fUserOffset;
377
378 double avg[2] = { 0, 0 };
379 double min[2] = { 90, 90 };
380 double max[2] = { -90, -90 };
381 int num[3] = { 0, 0, 0 };
382
383 vector<double> med[3];
384 med[0].resize(416);
385 med[1].resize(416);
386 med[2].resize(416);
387
388 struct dim_data
389 {
390 float I[416];
391 float Iavg;
392 float Irms;
393 float Imed;
394 float Idev;
395 uint32_t N;
396 float Tdiff;
397 float Uov[416];
398 float Unom;
399 float dUtemp;
400
401 dim_data() { memset(this, 0, sizeof(dim_data)); }
402 } __attribute__((__packed__));
403
404 int Ndev[3] = { 0, 0, 0 };
405
406 dim_data data;
407
408 data.Unom = overvoltage;
409 data.dUtemp = fTempOffsetAvg;
410
411 vector<float> vec(416);
412
413 /*
414 if (fEnableOldAlgorithm)
415 {
416 // ================================= old =======================
417 // Pixel 583: 5 31 == 191 (5) C2 B3 P3
418 // Pixel 830: 2 2 == 66 (4) C0 B8 P1
419 // Pixel 1401: 6 1 == 193 (5) C2 B4 P0
420
421 // 3900 Ohm/n + 1000 Ohm + 1100 Ohm (with n=4 or n=5)
422 const double R[2] = { 3075, 2870 };
423
424 const float *Iavg = fCalibration.data(); // Offset at U=fCalibrationOffset
425 const float *Ravg = fCalibration.data()+BIAS::kNumChannels*2; // Measured resistance
426
427 for (int i=0; i<320; i++)
428 {
429 const PixelMapEntry &hv = fMap.hv(i);
430 if (!hv)
431 continue;
432
433 // Average measured current
434 const double Im = Imes[i] * 1e6; // [uA]
435
436 // Group index (0 or 1) of the of the pixel (4 or 5 pixel patch)
437 const int g = hv.group();
438
439 // Serial resistors in front of the G-APD
440 double Rg = R[g];
441
442 // This is assuming that the broken pixels have a 390 Ohm instead of 3900 Ohm serial resistor
443 if (i==66) // Pixel 830(66)
444 Rg = 2400; // 2400 = (3/3900 + 1/390) + 1000 + 1100
445 if (i==191 || i==193) // Pixel 583(191) / Pixel 1401(193)
446 Rg = 2379; // 2379 = (4/3900 + 1/390) + 1000 + 1100
447
448 const double r = 1./(1./Rg + 1./Ravg[i]); // [Ohm]
449
450 // Offset induced by the voltage above the calibration point
451 const double Ubd = fVoltGapd[i] + fTempOffsets[i];
452 const double U0 = Ubd + overvoltage - fCalibVoltage[5][i]; // appliedOffset-fCalibrationOffset;
453 const double dI = U0/Ravg[i]; // [V/Ohm]
454
455 // Offset at the calibration point (make sure that the calibration is
456 // valid (Im[i]>Iavg[i]) and we operate above the calibration point)
457 const double I = Im>Iavg[i] ? Im - Iavg[i] : 0; // [uA]
458
459 // Make sure that the averaged resistor is valid
460 const double dU = Ravg[i]>10000 ? r*(I*1e-6 - dI) : 0;
461
462 vec[i] = Ubd + overvoltage + dU;
463
464 // Calculate statistics only for channels with a valid calibration
465 if (Iavg[i]>0)
466 {
467 med[g][num[g]] = dU;
468 avg[g] += dU;
469 num[g]++;
470
471 if (dU<min[g])
472 min[g] = dU;
473 if (dU>max[g])
474 max[g] = dU;
475
476 data.I[i] = Imes[i]*1e6 - fBiasVolt[i]/Ravg[i]*1e6;
477 data.I[i] /= hv.count();
478
479 if (i==66)
480 data.I[i] /= 1.3;
481 if (i==191 || i==193)
482 data.I[i] /= 1.4;
483
484 data.Iavg += data.I[i];
485 data.Irms += data.I[i]*data.I[i];
486
487 med[2][num[2]++] = data.I[i];
488 }
489 }
490 }
491 */
492
493 for (int i=0; i<320/*BIAS::kNumChannels*/; i++)
494 {
495 const PixelMapEntry &hv = fMap.hv(i);
496 if (!hv)
497 continue;
498
499 // Number of G-APDs in this patch
500 const int N = hv.count();
501
502 // Average measured ADC value for this channel
503 const double adc = Imes[i]/* * (5e-3/4096)*/; // [A]
504
505 // Current through ~100 Ohm measurement resistor
506 //const double I8 = (adc-fCalibDeltaI[i])*fCalibR8[i]/100;
507 const double I8 = adc-fCalibDeltaI[i];
508
509 // Current through calibration resistors (R9)
510 // This is uncalibrated, but since the corresponding calibrated
511 // value I8 is subtracted, the difference should yield a correct value
512 const double I9 = fBiasDac[i] * (1e-3/4096);//U9/R9; [A]
513
514 // Current in R4/R5 branch
515 //const double Iout = I8 - I9;//I8>I9 ? I8 - I9 : 0;
516 const double Iout = I8 - I9*100/fCalibR8[i];//I8>I9 ? I8 - I9 : 0;
517
518 // Applied voltage at calibration resistors, according to biasctrl
519 const double U9 = fBiasVolt[i];
520
521 // Serial resistors (one 1kOhm at the output of the bias crate, one 1kOhm in the camera)
522 const double R4 = 2000;
523
524 // Serial resistor of the individual G-APDs
525 double R5 = 3900./N;
526
527 // This is assuming that the broken pixels have a 390 Ohm instead of 3900 Ohm serial resistor
528 if (i==66) // Pixel 830(66)
529 R5 = 300; // 2400 = 1/(3/3900 + 1/390)
530 if (i==191 || i==193) // Pixel 583(191) / Pixel 1401(193)
531 R5 = 390/1.4; // 379 = 1/(4/3900 + 1/390)
532
533 // The measurement resistor
534 const double R8 = 100;
535
536 // Total resistance of branch with diodes (R4+R5)
537 // Assuming that the voltage output of the OpAMP is linear
538 // with the DAC setting and not the voltage at R9, the
539 // additional voltage drop at R8 must be taken into account
540 const double R = R4 + R5 + R8;
541
542 // For the patches with a broken resistor - ignoring the G-APD resistance -
543 // we get:
544 //
545 // I[R=3900] = Iout * 1/(10+(N-1)) = Iout /(N+9)
546 // I[R= 390] = Iout * (1 - 1/ (10+(N-1))) = Iout * (N+8)/(N+9)
547 //
548 // I[R=390] / I[R=3900] = N+8
549 //
550 // Udrp = Iout*3900/(N+9) + Iout*1000 + Iout*1000 = Iout * R
551
552 // Voltage drop in R4/R5 branch (for the G-APDs with correct resistor)
553 const double Udrp = R*Iout;
554
555 // Nominal breakdown voltage with correction for temperature dependence
556 const double Ubd = fVoltGapd[i] + fVoltOffset[i] + fTempOffset[i];
557
558 // Current overvoltage (at a G-APD with the correct 3900 Ohm resistor)
559 //const double Uov = U9-Udrp-Ubd>0 ? U9-Udrp-Ubd : 0;
560 const double Uov = U9-Udrp-Ubd>-0.34 ? U9-Udrp-Ubd : -0.34;
561
562 // Iout linear with U9 above Ubd
563 //
564 // Rx = (U9-Ubd)/Iout
565 // I' = (U9'-Ubd) / Rx
566 // Udrp' = R*I'
567 // Uov = U9' - Udrp' - Ubd
568 // Uov = overvoltage
569 //
570 // overvoltage = U9' - Udrp' - Ubd
571 // overvoltage = U9' - R*I' - Ubd
572 // overvoltage = U9' - R*((U9'-Ubd)/Rx) - Ubd
573 // overvoltage = U9' - U9'*R/Rx + Ubd*R/Rx - Ubd
574 // overvoltage = U9'*(1 - R/Rx) + Ubd*R/Rx - Ubd
575 // overvoltage - Ubd*R/Rx +Ubd = U9'*(1 - R/Rx)
576 // U9' = [ overvoltage - Ubd*R/Rx +Ubd ] / (1 - R/Rx)
577 //
578
579 // The current through one G-APD is the sum divided by the number of G-APDs
580 // (assuming identical serial resistors)
581 double Iapd = Iout/N;
582
583 // In this and the previosu case we neglect the resistance of the G-APDs, but we can make an
584 // assumption: The differential resistance depends more on the NSB than on the PDE,
585 // thus it is at least comparable for all G-APDs in the patch. In addition, although the
586 // G-APD with the 390Ohm serial resistor has the wrong voltage applied, this does not
587 // significantly influences the ohmic resistor or the G-APD because the differential
588 // resistor is large enough that the increase of the overvoltage does not dramatically
589 // increase the current flow as compared to the total current flow.
590 if (i==66 || i==191 || i==193)
591 Iapd = Iout/(N+9); // Iapd = R5*Iout/3900;
592
593 // The differential resistance of the G-APD, i.e. the dependence of the
594 // current above the breakdown voltage, is given by
595 //const double Rapd = Uov/Iapd;
596 // This allows us to estimate the current Iov at the overvoltage we want to apply
597 //const double Iov = overvoltage/Rapd;
598
599 // Estimate set point for over-voltage (voltage drop at the target point)
600 //const double Uset = Ubd + overvoltage + R*Iov*N;
601 //const double Uset = Uov<0.3 ? Ubd + overvoltage + Udrp : Ubd + overvoltage + Udrp*pow(overvoltage/Uov, 1.66);
602 const double Uset = Uov<0 ?
603 Ubd + overvoltage + Udrp*pow(overvoltage/0.34+1, 1.66) :
604 Ubd + overvoltage + Udrp*pow((overvoltage+0.34)/(Uov+0.34), 1.66);
605
606 if (fabs(overvoltage-Uov)>0.033)
607 Ndev[0]++;
608 if (fabs(overvoltage-Uov)>0.022)
609 Ndev[1]++;
610 if (fabs(overvoltage-Uov)>0.011)
611 Ndev[2]++;
612
613 // Voltage set point
614 vec[i] = Uset;
615
616 /*
617 if (fDimBias.state()==BIAS::State::kVoltageOn && GetCurrentState()==Feedback::State::kInProgress &&
618 fabs(Uov-overvoltage)>0.033)
619 cout << setprecision(4) << setw(3) << i << ": Uov=" << Uov << " Udrp=" << Udrp << " Iapd=" << Iapd*1e6 << endl;
620 */
621
622 // Calculate statistics only for channels with a valid calibration
623 //if (Uov>0)
624 {
625 const int g = hv.group();
626
627 med[g][num[g]] = Uov;
628 avg[g] += Uov;
629 num[g]++;
630
631 if (Uov<min[g])
632 min[g] = Uov;
633 if (Uov>max[g])
634 max[g] = Uov;
635
636 const double iapd = Iapd*1e6; // A --> uA
637
638 data.I[i] = iapd;
639 data.Iavg += iapd;
640 data.Irms += iapd*iapd;
641
642 data.Uov[i] = Uov;
643
644 med[2][num[2]++] = iapd;
645 }
646 }
647
648 // ------------------------------- Update voltages ------------------------------------
649
650 if (GetCurrentState()!=Feedback::State::kCalibrated) // WaitingForData, InProgress
651 {
652 if (fDimBias.state()!=BIAS::State::kRamping)
653 {
654 DimClient::sendCommandNB("BIAS_CONTROL/SET_ALL_CHANNELS_VOLTAGE",
655 vec.data(), BIAS::kNumChannels*sizeof(float));
656
657 ostringstream msg;
658 msg << setprecision(4) << "Sending new absolute offset: dU(" << fTemp << "degC)=" << fTempOffsetAvg << "V+-" << fTempOffsetRms << ", Unom=" << overvoltage << "V, Uov=" << (num[0]+num[1]>0?(avg[0]+avg[1])/(num[0]+num[1]):0) << " [N=" << Ndev[0] << "/" << Ndev[1] << "/" << Ndev[2] << "]";
659 Info(msg);
660 }
661 }
662 else
663 {
664 if (fDimBias.state()==BIAS::State::kVoltageOn)
665 {
666 ostringstream msg;
667 msg << setprecision(4) << "Current status: dU(" << fTemp << "degC)=" << fTempOffsetAvg << "V+-" << fTempOffsetRms << ", Unom=" << overvoltage << "V, Uov=" << (num[0]+num[1]>0?(avg[0]+avg[1])/(num[0]+num[1]):0) << " [N=" << Ndev[0] << "/" << Ndev[1] << "/" << Ndev[2] << "]";
668 Info(msg);
669 }
670
671 }
672
673 if (GetCurrentState()==Feedback::State::kInProgress &&
674 fDimBias.state()==BIAS::State::kRamping)
675 return GetCurrentState();
676
677 // --------------------------------- Console out --------------------------------------
678
679 if (num[0]>0 && num[1]>0 && fIsVerbose && !fDimBias.state()==BIAS::State::kRamping)
680 {
681 sort(med[0].begin(), med[0].begin()+num[0]);
682 sort(med[1].begin(), med[1].begin()+num[1]);
683
684 ostringstream msg;
685 msg << " Avg0=" << setw(7) << avg[0]/num[0] << " | Avg1=" << setw(7) << avg[1]/num[1];
686 Debug(msg);
687
688 msg.str("");
689 msg << " Med0=" << setw(7) << med[0][num[0]/2] << " | Med1=" << setw(7) << med[1][num[1]/2];
690 Debug(msg);
691
692 msg.str("");
693 msg << " Min0=" << setw(7) << min[0] << " | Min1=" << setw(7) << min[1];
694 Debug(msg);
695
696 msg.str("");
697 msg << " Max0=" << setw(7) << max[0] << " | Max1=" << setw(7) << max[1];
698 Debug(msg);
699 }
700
701 // ---------------------------- Calibrated Currents -----------------------------------
702
703 if (num[2]>0)
704 {
705 data.Iavg /= num[2];
706 data.Irms /= num[2];
707 data.Irms -= data.Iavg*data.Iavg;
708
709 data.N = num[2];
710 data.Irms = data.Irms<0 ? 0: sqrt(data.Irms);
711
712 sort(med[2].data(), med[2].data()+num[2]);
713
714 data.Imed = num[2]%2 ? med[2][num[2]/2] : (med[2][num[2]/2-1]+med[2][num[2]/2])/2;
715
716 for (int i=0; i<num[2]; i++)
717 med[2][i] = fabs(med[2][i]-data.Imed);
718
719 sort(med[2].data(), med[2].data()+num[2]);
720
721 data.Idev = med[2][uint32_t(0.682689477208650697*num[2])];
722
723 data.Tdiff = evt.GetTime().UnixTime()-fTimeCalib.UnixTime();
724
725 // FIXME:
726 // + Current overvoltage
727 // + Temp offset
728 // + User offset
729 // + Command overvoltage
730 fDimCurrents.setQuality(GetCurrentState());
731 fDimCurrents.setData(&data, sizeof(dim_data));
732 fDimCurrents.Update(evt.GetTime());
733 }
734
735 return GetCurrentState()==Feedback::State::kCalibrated ? Feedback::State::kCalibrated : Feedback::State::kInProgress;
736 }
737
738 // ======================================================================
739
740 int Print() const
741 {
742 Out() << fDim << endl;
743 Out() << fDimFSC << endl;
744 Out() << fDimBias << endl;
745
746 return GetCurrentState();
747 }
748
749 int PrintCalibration()
750 {
751 /*
752 if (fCalibration.size()==0)
753 {
754 Out() << "No calibration performed so far." << endl;
755 return GetCurrentState();
756 }
757
758 const float *avg = fCalibration.data();
759 const float *rms = fCalibration.data()+BIAS::kNumChannels;
760 const float *res = fCalibration.data()+BIAS::kNumChannels*2;
761
762 Out() << "Average current at " << fCalibrationOffset << "V below G-APD operation voltage:\n";
763
764 for (int k=0; k<13; k++)
765 for (int j=0; j<8; j++)
766 {
767 Out() << setw(2) << k << "|" << setw(2) << j*4 << "|";
768 for (int i=0; i<4; i++)
769 Out() << Tools::Form(" %6.1f+-%4.1f", avg[k*32+j*4+i], rms[k*32+j*4+i]);
770 Out() << '\n';
771 }
772 Out() << '\n';
773
774 Out() << "Measured calibration resistor:\n";
775 for (int k=0; k<13; k++)
776 for (int j=0; j<4; j++)
777 {
778 Out() << setw(2) << k << "|" << setw(2) << j*8 << "|";
779 for (int i=0; i<8; i++)
780 Out() << Tools::Form(" %5.0f", res[k*32+j*8+i]);
781 Out() << '\n';
782 }
783
784 Out() << flush;
785 */
786 return GetCurrentState();
787 }
788
789 int SetVerbosity(const EventImp &evt)
790 {
791 if (!CheckEventSize(evt.GetSize(), "SetVerbosity", 1))
792 return kSM_FatalError;
793
794 fIsVerbose = evt.GetBool();
795
796 return GetCurrentState();
797 }
798
799 int SetCurrentRequestInterval(const EventImp &evt)
800 {
801 if (!CheckEventSize(evt.GetSize(), "SetCurrentRequestInterval", 2))
802 return kSM_FatalError;
803
804 fCurrentRequestInterval = evt.GetUShort();
805
806 Info("New current request interval: "+to_string(fCurrentRequestInterval)+"ms");
807
808 return GetCurrentState();
809 }
810
811 int Calibrate()
812 {
813 if (fDimBias.state()!=BIAS::State::kVoltageOff)
814 {
815 Warn("Calibration can only be started when biasctrl is in state VoltageOff.");
816 return GetCurrentState();
817 }
818
819 Message("Starting calibration (ignore="+to_string(fNumCalibIgnore)+", N="+to_string(fNumCalibRequests)+")");
820
821 fCursorCur = -fNumCalibIgnore;
822 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
823 fCurrentsRms.assign(BIAS::kNumChannels, 0);
824
825 fBiasDac.assign(BIAS::kNumChannels, 0);
826
827 fCalibStep = 3;
828 fTimeCalib = Time();
829
830 Dim::SendCommandNB("BIAS_CONTROL/SET_GLOBAL_DAC", uint32_t(256+512*fCalibStep));
831
832 return Feedback::State::kCalibrating;
833 }
834
835 int Start(const EventImp &evt)
836 {
837 if (!CheckEventSize(evt.GetSize(), "Start", 4))
838 return kSM_FatalError;
839
840 if (fDimBias.state()==BIAS::State::kRamping)
841 {
842 Warn("Feedback can not be started when biasctrl is in state Ramping.");
843 return GetCurrentState();
844 }
845
846 fUserOffset = evt.GetFloat();
847
848 fCursorCur = 0;
849
850 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
851 fCurrentsRms.assign(BIAS::kNumChannels, 0);
852
853 ostringstream out;
854 out << "Starting feedback with an offset of " << fUserOffset << "V";
855 Message(out);
856
857 return Feedback::State::kWaitingForData;
858 }
859
860 int StopFeedback()
861 {
862 if (GetCurrentState()==Feedback::State::kCalibrating)
863 return Feedback::State::kConnected;
864
865 if (GetCurrentState()>Feedback::State::kCalibrated)
866 return Feedback::State::kCalibrated;
867
868 return GetCurrentState();
869 }
870
871 bool LoadOffsets(const string &file)
872 {
873 vector<double> data(416);
874
875 ifstream fin(file);
876
877 int cnt = 0;
878 while (fin && cnt<320)
879 fin >> data[cnt++];
880
881 if (cnt!=320)
882 {
883 Error("Reading offsets from "+file+" failed [N="+to_string(cnt-1)+"]");
884 return false;
885 }
886
887 fVoltOffset = data;
888
889 fDimOffsets.Update(fVoltOffset);
890
891 Info("New voltage offsets loaded from "+file);
892 return true;
893
894 }
895
896 int LoadOffset(const EventImp &evt)
897 {
898 LoadOffsets(evt.GetText());
899 return GetCurrentState();
900 }
901
902 int ResetOffset()
903 {
904 fVoltOffset.assign(416, 0);
905
906 fDimOffsets.Update(fVoltOffset);
907
908 Info("Voltage offsets resetted.");
909 return GetCurrentState();
910 }
911
912
913 int Execute()
914 {
915 if (!fDim.online())
916 return Feedback::State::kDimNetworkNA;
917
918 const bool bias = fDimBias.state() >= BIAS::State::kConnecting;
919 const bool fsc = fDimFSC.state() >= FSC::State::kConnected;
920
921 // All subsystems are not connected
922 if (!bias && !fsc)
923 return Feedback::State::kDisconnected;
924
925 // Not all subsystems are yet connected
926 if (!bias || !fsc)
927 return Feedback::State::kConnecting;
928
929 if (GetCurrentState()<Feedback::State::kCalibrating)
930 return Feedback::State::kConnected;
931
932 if (GetCurrentState()==Feedback::State::kConnected)
933 return GetCurrentState();
934 if (GetCurrentState()==Feedback::State::kCalibrating)
935 return GetCurrentState();
936
937 // kCalibrated, kWaitingForData, kInProgress
938
939 if (fDimBias.state()==BIAS::State::kVoltageOn || (fDimBias.state()==BIAS::State::kVoltageOff && GetCurrentState()==Feedback::State::kWaitingForData))
940 {
941 static Time past;
942 if (fCurrentRequestInterval>0 && Time()-past>boost::posix_time::milliseconds(fCurrentRequestInterval))
943 {
944 Dim::SendCommandNB("BIAS_CONTROL/REQUEST_STATUS");
945 past = Time();
946 }
947 }
948
949 return GetCurrentState();
950 }
951
952public:
953 StateMachineFeedback(ostream &out=cout) : StateMachineDim(out, "FEEDBACK"),
954 fIsVerbose(false),
955 //---
956 fDimFSC("FSC_CONTROL"),
957 fDimBias("BIAS_CONTROL"),
958 //---
959 fDimCalibration("FEEDBACK/CALIBRATION", "F:416;F:416;F:416;F:416",
960 "Current offsets"
961 "|Avg[uA]:Average offset at dac=256+5*512"
962 "|Rms[uA]:Rms of Avg"
963 "|R[Ohm]:Measured calibration resistor"
964 "|U[V]:Corresponding voltage reported by biasctrl"),
965 fDimCalibration2("FEEDBACK/CALIBRATION_STEPS", "I:1;F:416;F:416;F:416",
966 "Calibration of the R8 resistor"
967 "|DAC[dac]:DAC setting"
968 "|U[V]:Corresponding voltages reported by biasctrl"
969 "|Iavg[uA]:Averaged measured current"
970 "|Irms[uA]:Rms measured current"),
971 fDimCalibrationR8("FEEDBACK/CALIBRATION_R8", "F:416;F:416",
972 "Calibration of R8"
973 "|DeltaI[uA]:Average offset"
974 "|R8[uA]:Measured effective resistor R8"),
975 fDimCurrents("FEEDBACK/CALIBRATED_CURRENTS", "F:416;F:1;F:1;F:1;F:1;I:1;F:1;F:416;F:1;F:1",
976 "Calibrated currents"
977 "|I[uA]:Calibrated currents per pixel"
978 "|I_avg[uA]:Average calibrated current (N channels)"
979 "|I_rms[uA]:Rms of calibrated current (N channels)"
980 "|I_med[uA]:Median calibrated current (N channels)"
981 "|I_dev[uA]:Deviation of calibrated current (N channels)"
982 "|N[uint16]:Number of valid values"
983 "|T_diff[s]:Time difference to calibration"
984 "|U_ov[V]:Calculated overvoltage"
985 "|U_nom[V]:Nominal overvoltage"
986 "|dU_temp[V]:Correction calculated from temperature"
987 ),
988 fDimOffsets("FEEDBACK/OFFSETS", "F:416",
989 "Offsets operation voltages"
990 "|U[V]:Offset per bias channels"),
991 fVoltOffset(416),
992 fCurrentRequestInterval(0),
993 fNumCalibIgnore(30),
994 fNumCalibRequests(300)
995 {
996 fDim.Subscribe(*this);
997 fDimFSC.Subscribe(*this);
998 fDimBias.Subscribe(*this);
999
1000 fDimBias.SetCallback(bind(&StateMachineFeedback::HandleBiasStateChange, this));
1001
1002 Subscribe("BIAS_CONTROL/CURRENT")
1003 (bind(&StateMachineFeedback::HandleBiasCurrent, this, placeholders::_1));
1004 Subscribe("BIAS_CONTROL/VOLTAGE")
1005 (bind(&StateMachineFeedback::HandleBiasVoltage, this, placeholders::_1));
1006 Subscribe("BIAS_CONTROL/DAC")
1007 (bind(&StateMachineFeedback::HandleBiasDac, this, placeholders::_1));
1008 Subscribe("BIAS_CONTROL/NOMINAL")
1009 (bind(&StateMachineFeedback::HandleBiasNom, this, placeholders::_1));
1010 Subscribe("FSC_CONTROL/BIAS_TEMP")
1011 (bind(&StateMachineFeedback::HandleCameraTemp, this, placeholders::_1));
1012
1013 // State names
1014 AddStateName(Feedback::State::kDimNetworkNA, "DimNetworkNotAvailable",
1015 "The Dim DNS is not reachable.");
1016
1017 AddStateName(Feedback::State::kDisconnected, "Disconnected",
1018 "The Dim DNS is reachable, but the required subsystems are not available.");
1019 AddStateName(Feedback::State::kConnecting, "Connecting",
1020 "Either biasctrl or fscctrl not connected.");
1021 AddStateName(Feedback::State::kConnected, "Connected",
1022 "biasctrl and fscctrl are available and connected with their hardware.");
1023
1024 AddStateName(Feedback::State::kCalibrating, "Calibrating",
1025 "Bias crate calibrating in progress.");
1026 AddStateName(Feedback::State::kCalibrated, "Calibrated",
1027 "Bias crate calibrated.");
1028
1029 AddStateName(Feedback::State::kWaitingForData, "WaitingForData",
1030 "Current control started, waiting for valid temperature and current data.");
1031 AddStateName(Feedback::State::kInProgress, "InProgress",
1032 "Current control in progress.");
1033
1034
1035 /*
1036 AddEvent("SET_CURRENT_REQUEST_INTERVAL")
1037 (bind(&StateMachineFeedback::SetCurrentRequestInterval, this, placeholders::_1))
1038 ("|interval[ms]:Interval between two current requests in modes which need that.");
1039 */
1040
1041 AddEvent("CALIBRATE", Feedback::State::kConnected, Feedback::State::kCalibrated)
1042 (bind(&StateMachineFeedback::Calibrate, this))
1043 ("");
1044
1045 AddEvent("START", "F:1", Feedback::State::kCalibrated)
1046 (bind(&StateMachineFeedback::Start, this, placeholders::_1))
1047 ("Start the current/temperature control loop"
1048 "|Uov[V]:Overvoltage to be applied (standard value is 1.1V)");
1049
1050 AddEvent("STOP")
1051 (bind(&StateMachineFeedback::StopFeedback, this))
1052 ("Stop any control loop");
1053
1054 AddEvent("LOAD_OFFSETS", "C", Feedback::State::kConnected, Feedback::State::kCalibrated)
1055 (bind(&StateMachineFeedback::LoadOffset, this, placeholders::_1))
1056 ("");
1057 AddEvent("RESET_OFFSETS", Feedback::State::kConnected, Feedback::State::kCalibrated)
1058 (bind(&StateMachineFeedback::ResetOffset, this))
1059 ("");
1060
1061
1062 AddEvent("PRINT")
1063 (bind(&StateMachineFeedback::Print, this))
1064 ("");
1065 AddEvent("PRINT_CALIBRATION")
1066 (bind(&StateMachineFeedback::PrintCalibration, this))
1067 ("");
1068
1069 // Verbosity commands
1070 AddEvent("SET_VERBOSE", "B:1")
1071 (bind(&StateMachineFeedback::SetVerbosity, this, placeholders::_1))
1072 ("set verbosity state"
1073 "|verbosity[bool]:disable or enable verbosity when calculating overvoltage");
1074 }
1075
1076 int EvalOptions(Configuration &conf)
1077 {
1078 fIsVerbose = !conf.Get<bool>("quiet");
1079
1080 if (!fMap.Read(conf.Get<string>("pixel-map-file")))
1081 {
1082 Error("Reading mapping table from "+conf.Get<string>("pixel-map-file")+" failed.");
1083 return 1;
1084 }
1085
1086 fCurrentRequestInterval = conf.Get<uint16_t>("current-request-interval");
1087 fNumCalibIgnore = conf.Get<uint16_t>("num-calib-ignore");
1088 fNumCalibRequests = conf.Get<uint16_t>("num-calib-average");
1089 fTempCoefficient = conf.Get<double>("temp-coefficient");
1090
1091 if (conf.Has("offset-file"))
1092 LoadOffsets(conf.Get<string>("offset-file"));
1093
1094 return -1;
1095 }
1096};
1097
1098// ------------------------------------------------------------------------
1099
1100#include "Main.h"
1101
1102template<class T>
1103int RunShell(Configuration &conf)
1104{
1105 return Main::execute<T, StateMachineFeedback>(conf);
1106}
1107
1108void SetupConfiguration(Configuration &conf)
1109{
1110 po::options_description control("Feedback options");
1111 control.add_options()
1112 ("quiet,q", po_bool(true), "Disable printing more information on average overvoltagecontents of all received messages (except dynamic data) in clear text.")
1113 ("pixel-map-file", var<string>()->required(), "Pixel mapping file. Used here to get the default reference voltage.")
1114 ("current-request-interval", var<uint16_t>(1000), "Interval between two current requests.")
1115 ("num-calib-ignore", var<uint16_t>(30), "Number of current requests to be ignored before averaging")
1116 ("num-calib-average", var<uint16_t>(300), "Number of current requests to be averaged")
1117 ("temp-coefficient", var<double>()->required(), "Temp. coefficient [V/K]")
1118 ("offset-file", var<string>(), "File with operation voltage offsets")
1119 ;
1120
1121 conf.AddOptions(control);
1122}
1123
1124/*
1125 Extract usage clause(s) [if any] for SYNOPSIS.
1126 Translators: "Usage" and "or" here are patterns (regular expressions) which
1127 are used to match the usage synopsis in program output. An example from cp
1128 (GNU coreutils) which contains both strings:
1129 Usage: cp [OPTION]... [-T] SOURCE DEST
1130 or: cp [OPTION]... SOURCE... DIRECTORY
1131 or: cp [OPTION]... -t DIRECTORY SOURCE...
1132 */
1133void PrintUsage()
1134{
1135 cout <<
1136 "The feedback control the BIAS voltages based on the calibration signal.\n"
1137 "\n"
1138 "The default is that the program is started without user intercation. "
1139 "All actions are supposed to arrive as DimCommands. Using the -c "
1140 "option, a local shell can be initialized. With h or help a short "
1141 "help message about the usuage can be brought to the screen.\n"
1142 "\n"
1143 "Usage: feedback [-c type] [OPTIONS]\n"
1144 " or: feedback [OPTIONS]\n";
1145 cout << endl;
1146}
1147
1148void PrintHelp()
1149{
1150 Main::PrintHelp<StateMachineFeedback>();
1151
1152 /* Additional help text which is printed after the configuration
1153 options goes here */
1154
1155 /*
1156 cout << "bla bla bla" << endl << endl;
1157 cout << endl;
1158 cout << "Environment:" << endl;
1159 cout << "environment" << endl;
1160 cout << endl;
1161 cout << "Examples:" << endl;
1162 cout << "test exam" << endl;
1163 cout << endl;
1164 cout << "Files:" << endl;
1165 cout << "files" << endl;
1166 cout << endl;
1167 */
1168}
1169
1170int main(int argc, const char* argv[])
1171{
1172 Configuration conf(argv[0]);
1173 conf.SetPrintUsage(PrintUsage);
1174 Main::SetupConfiguration(conf);
1175 SetupConfiguration(conf);
1176
1177 if (!conf.DoParse(argc, argv, PrintHelp))
1178 return 127;
1179
1180 //try
1181 {
1182 // No console access at all
1183 if (!conf.Has("console"))
1184 {
1185// if (conf.Get<bool>("no-dim"))
1186// return RunShell<LocalStream, StateMachine, ConnectionFSC>(conf);
1187// else
1188 return RunShell<LocalStream>(conf);
1189 }
1190 // Cosole access w/ and w/o Dim
1191/* if (conf.Get<bool>("no-dim"))
1192 {
1193 if (conf.Get<int>("console")==0)
1194 return RunShell<LocalShell, StateMachine, ConnectionFSC>(conf);
1195 else
1196 return RunShell<LocalConsole, StateMachine, ConnectionFSC>(conf);
1197 }
1198 else
1199*/ {
1200 if (conf.Get<int>("console")==0)
1201 return RunShell<LocalShell>(conf);
1202 else
1203 return RunShell<LocalConsole>(conf);
1204 }
1205 }
1206 /*catch (std::exception& e)
1207 {
1208 cerr << "Exception: " << e.what() << endl;
1209 return -1;
1210 }*/
1211
1212 return 0;
1213}
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