source: trunk/FACT++/src/feedback.cc@ 16329

Last change on this file since 16329 was 16282, checked in by tbretz, 12 years ago
Replaced push_back by emplac_back were reasonable.
File size: 61.3 KB
Line 
1#include <valarray>
2
3#include "Dim.h"
4#include "Event.h"
5#include "Shell.h"
6#include "StateMachineDim.h"
7#include "Connection.h"
8#include "Configuration.h"
9#include "Console.h"
10#include "Converter.h"
11#include "externals/PixelMap.h"
12
13#include "tools.h"
14
15#include "LocalControl.h"
16
17#include "HeadersFAD.h"
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 enum control_t
33 {
34 kIdle,
35 kTemp,
36 kFeedback,
37 kFeedbackGlobal,
38 kCurrents,
39 kCurrentsNew,
40 };
41
42 control_t fControlType;
43
44 PixelMap fMap;
45
46 DimVersion fDim;
47 DimDescribedState fDimFAD;
48 DimDescribedState fDimFSC;
49 DimDescribedState fDimBias;
50
51 DimDescribedService fDimReference;
52 DimDescribedService fDimDeviation;
53 DimDescribedService fDimCalibration;
54 DimDescribedService fDimCurrents;
55
56 vector<int64_t> fCurrentsAvg;
57 vector<int64_t> fCurrentsRms;
58
59 vector<float> fCalibration;
60 vector<float> fVoltGapd;
61 vector<float> fBiasVolt;
62
63 vector<vector<float>> fData;
64
65 int64_t fCursorCur;
66 uint64_t fCursorAmpl;
67 uint64_t fCursorTemp;
68
69 Time fBiasLast;
70 Time fStartTime;
71 Time fCalibTime;
72
73 valarray<double> fPV[3]; // Process variable (intgerated/averaged amplitudes)
74 valarray<double> fSP; // Set point (target amplitudes)
75
76 double fKp; // Proportional constant
77 double fKi; // Integral constant
78 double fKd; // Derivative constant
79 double fT; // Time constant (cycle time)
80 double fGain; // Gain (conversion from a DRS voltage deviation into a BIAS voltage change at G-APD reference voltage)
81
82 double fT21;
83
84 double fBiasOffset;
85 double fTempOffset;
86 double fCalibrationOffset;
87 double fAppliedOffset;
88
89 uint16_t fCurrentRequestInterval;
90 uint16_t fNumCalibIgnore;
91 uint16_t fNumCalibRequests;
92
93 bool fOutputEnabled;
94
95 int HandleCameraTemp(const EventImp &evt)
96 {
97 if (fControlType!=kTemp && fControlType!=kCurrents && fControlType!=kCurrentsNew)
98 return GetCurrentState();
99
100 if (evt.GetSize()!=60*sizeof(float))
101 return GetCurrentState();
102
103 const float *ptr = evt.Ptr<float>();
104
105 double avgt = 0;
106 int numt = 0;
107 for (int i=1; i<32; i++)
108 if (ptr[i]!=0)
109 {
110 avgt += ptr[i];
111 numt++;
112 }
113
114 if (numt==0)
115 {
116 Warn("Received sensor temperatures all invalid.");
117 return GetCurrentState();
118 }
119
120 avgt /= numt; // [deg C]
121
122 fTempOffset = (avgt-25)*4./70; // [V]
123
124 fCursorTemp++;
125
126 return fControlType==kCurrentsNew ? HandleCurrentControlNew() : HandleCurrentControl();
127 }
128
129 int HandleCurrentControlNew()
130 {
131 if (GetCurrentState()==Feedback::State::kCalibrating && fBiasOffset>fTempOffset-1.2)
132 {
133 fCursorTemp = 0;
134
135 ostringstream msg;
136 msg << " (applied calibration offset " << fBiasOffset << "V exceeds temperature correction " << fTempOffset << "V - 1.2V.";
137 Warn("Trying to calibrate above G-APD breakdown volatge!");
138 Warn(msg);
139 return GetCurrentState();
140 }
141
142 double avg[2] = { 0, 0 };
143 double min[2] = { 90, 90 };
144 double max[2] = { -90, -90 };
145 int num[2] = { 0, 0 };
146
147 vector<double> med[2];
148 med[0].resize(416);
149 med[1].resize(416);
150
151 const float *Ravg = fCalibration.data()+BIAS::kNumChannels*2; // Measured resistance
152
153 vector<float> vec(2*BIAS::kNumChannels+2);
154
155 vec[BIAS::kNumChannels*2] = fTempOffset;
156 vec[BIAS::kNumChannels*2+1] = fBiasOffset;
157
158 float *Uoff = vec.data()+BIAS::kNumChannels;
159
160 if (GetCurrentState()==Feedback::State::kCalibrating)
161 for (int i=0; i<BIAS::kNumChannels; i++)
162 Uoff[i] = fBiasOffset;
163 else
164 for (int i=0; i<BIAS::kNumChannels; i++)
165 Uoff[i] = fTempOffset+fBiasOffset;
166
167 if (fControlType==kCurrentsNew)
168 {
169 // Would be a devision by zero. We need informations first.
170 if (fCursorCur==0)
171 return GetCurrentState();
172
173 for (int i=0; i<BIAS::kNumChannels; i++)
174 {
175 const PixelMapEntry &hv = fMap.hv(i);
176 if (!hv)
177 continue;
178
179 // Nominal breakdown voltage (includes overvoltage already)
180 double Ubd = fVoltGapd[i];
181
182 // Nominal breakdown voltage excluding overvoltage of 1.1V
183 Ubd -= 1.1;
184
185 // Correct breakdown voltage for temperature dependence
186 Ubd += fTempOffset;
187
188 // Number of G-APDs in this patch
189 const int N = hv.group() ? 5 : 4;
190
191 // 100 Ohm measurement resistor for current measurement
192 const double R2 = 100;
193
194 // Serial resistors (one 1kOhm at the output of the bias crate, one 1kOhm in the camera)
195 const double R4 = 2000;
196
197 // Serial resistor of the individual G-APDs
198 double R5 = 3900/N;
199
200 // This is assuming that the broken pixels have a 390 Ohm instead of 3900 Ohm serial resistor
201 if (i==66) // Pixel 830(66)
202 R5 = 300; // 2400 = 1/(3/3900 + 1/390)
203 if (i==191 || i==193) // Pixel 583(191) / Pixel 1401(193)
204 R5 = 390/1.4; // 379 = 1/(4/3900 + 1/390)
205
206 // Total resistance of branch with diode
207 const double R3 = R4+R5;
208
209 // Measured calibration resistor
210 const double R1 = Ravg[i] - R2;
211
212 // Voltage output of bias crate
213 const double Uout = fBiasVolt[i];
214
215 // Average current measured for this channel
216 const double Imes = double(fCurrentsAvg[i])/fCursorCur * (5000/4096.); // [uA]
217
218 // Voltage drop at measurement resistor R2 is define
219 // bythe measured current and the resistor
220 const double U2 = R2*Imes;
221
222 // The voltage seen by the calibration resistor R1 is defined by the
223 // bias crate output voltage minus the drop at the measurement resistor R2
224 const double U1 = Uout - U2;
225
226 // The current through the resistor R1 is defined
227 // by the applied voltage and the resistor
228 const double I1 = U1/R1;
229
230 // The current through the diode branch is the measured current
231 // minus the current through the calibration resistor R1
232 const double I3 = Imes - I1;
233
234 // The voltage drop in the diode branch (without the diode) is defined by the
235 // resistor and the current. It is 0 below the breakdown voltage of the G-APD
236 // is reached at the G-APD. This is the case when the output voltage minus
237 // the voltage drop at the calibration resistor reaches the breakdown voltage.
238 const double U3 = Uout-U2<Ubd ? 0 : R3*I3;
239
240 // Voltage drop at measurement resistor R2 and
241 // the total serial resistor R3 in the diode branch
242 const double Udrp = U2 + U3;
243
244 // Voltage finally at each G-APD (bias crate output voltage minus voltage drop)
245 const double Uapd = Uout - Udrp;
246
247 // The over-voltage seen by the G-APD (the voltage above the breakdown voltage) is
248 const double Uov = Uapd<Ubd ? 0 : Uapd - Ubd;
249
250 // The current through one G-APD is the sum divided by the number of G-APDs
251 // (assuming identical serial resistors)
252 double Iapd = I3/N;
253
254 // This is assuming that the broken pixels have a 390 Ohm instead of 3900 Ohm serial resistor
255 // In this and the previosu case we neglect the resistance of the G-APDs, but we can make an
256 // assumption: The differential resistance depends more on the NSB than on the PDE,
257 // thus it is at least comparable for all G-APDs in the patch. In addition, although the
258 // G-APD with the 390Ohm serial resistor has the wrong voltage applied, this does not
259 // significantly influences the ohmic resistor or the G-APD because the differential
260 // resistor is large enough that the increase of the overvoltage does not dramatically
261 // increase the current flow as compared to the total current flow.
262 if (i==66)
263 Iapd *= 1.3;
264 if (i==191 || i==193)
265 Iapd *= 1.4;
266
267 // If the G-APD voltage is above the breakdown voltage we have the current through the
268 // G-APD and the over-voltage applied to the G-APD to calculate its differential resistor.
269 if (Uapd>Ubd)
270 {
271 // The differential resistance of the G-APD, i.e. the dependence of the
272 // current above the breakdown voltage, is given by
273 const double Rapd = Uov/Iapd;
274
275 // This allows us to estimate the current Iov at the overvoltage we want to apply
276 const double Iov = (1.1+fBiasOffset)/Rapd;
277
278 // This gives us an ohmic resistance Rov of the G-APD at the set-point
279 const double Rest = (Ubd+1.1+fBiasOffset)/Iov;
280
281 // This lets us estimate the total resistance Rtot of the circuit at the set-point
282 const double R3b = R4 + (R5+Rest)/N;
283 const double Rtot = R2 + 1/(1/R1 + 1/R3b);
284
285 // From this we can estimate the output voltage we need to get the
286 // over-voltage at the G-APD as anticipated
287 const double r = 1 + R3/R1 - (R2 + R3 + R3*R2/R1)/Rtot;
288 const double Uset = (Ubd+1.1+fBiasOffset)/r;
289
290 Uoff[i] = Uset - fVoltGapd[i];
291 }
292
293 // Calculate statistics only for channels with a valid calibration
294 if (Uov>0)
295 {
296 const int g = hv.group();
297
298 med[g][num[g]] = Uov;
299 avg[g] += Uov;
300 num[g]++;
301
302 if (Uov<min[g])
303 min[g] = Uov;
304 if (Uov>max[g])
305 max[g] = Uov;
306 }
307 }
308
309 sort(med[0].begin(), med[0].begin()+num[0]);
310 sort(med[1].begin(), med[1].begin()+num[1]);
311
312 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
313 fCursorCur = 0;
314 }
315
316 fDimDeviation.setQuality(fControlType);
317 fDimDeviation.Update(vec);
318
319 // Warning: Here it is assumed that the ramp up and down is done properly
320 // within the time between two new temperatures and that the calibration
321 // is finished within that time.
322 if (GetCurrentState()!=Feedback::State::kCalibrating ||
323 fDimBias.state()!=BIAS::State::kVoltageOff ||
324 fCursorTemp!=1 || !fOutputEnabled)
325 {
326 if (!fOutputEnabled || fDimBias.state()!=BIAS::State::kVoltageOn)
327 return GetCurrentState();
328
329 // Trigger calibration
330 if (GetCurrentState()==Feedback::State::kCalibrating && fCursorTemp==2)
331 {
332 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
333 return GetCurrentState();
334 }
335 }
336
337 ostringstream msg;
338 msg << setprecision(4) << "Sending new absolute offset (" << fAppliedOffset << "V+" << (num[0]+num[1]>0?(avg[0]+avg[1])/(num[0]+num[1]):0) << "V) to biasctrl.";
339 Info(msg);
340
341 if (fControlType==kCurrents && num[0]>0 && num[1]>0)
342 {
343 msg.str("");
344 msg << " Avg0=" << setw(7) << avg[0]/num[0] << " | Avg1=" << setw(7) << avg[1]/num[1];
345 Debug(msg);
346
347 msg.str("");
348 msg << " Med0=" << setw(7) << med[0][num[0]/2] << " | Med1=" << setw(7) << med[1][num[1]/2];
349 Debug(msg);
350
351 msg.str("");
352 msg << " Min0=" << setw(7) << min[0] << " | Min1=" << setw(7) << min[1];
353 Debug(msg);
354
355 msg.str("");
356 msg << " Max0=" << setw(7) << max[0] << " | Max1=" << setw(7) << max[1];
357 Debug(msg);
358 }
359
360 DimClient::sendCommandNB("BIAS_CONTROL/SET_ALL_CHANNELS_OFFSET",
361 vec.data()+BIAS::kNumChannels, BIAS::kNumChannels*sizeof(float));
362
363 return GetCurrentState();
364 }
365
366 int HandleCurrentControl()
367 {
368 const double dUt = fTempOffset; // [V]
369
370 if (GetCurrentState()==Feedback::State::kCalibrating && fBiasOffset>dUt-1.2)
371 {
372 fCursorTemp = 0;
373
374 ostringstream msg;
375 msg << " (applied calibration offset " << fBiasOffset << "V exceeds temperature correction " << fTempOffset << "V - 1.2V.";
376 Warn("Trying to calibrate above G-APD breakdown volatge!");
377 Warn(msg);
378 return GetCurrentState();
379 }
380
381 // FIXME: If calibrating do not wait for the temperature!
382 fAppliedOffset = fBiasOffset;
383 if (GetCurrentState()!=Feedback::State::kCalibrating)
384 fAppliedOffset += dUt;
385
386 vector<float> vec(2*BIAS::kNumChannels+2);
387 for (int i=0; i<BIAS::kNumChannels; i++)
388 vec[i+BIAS::kNumChannels] = fAppliedOffset;
389
390 vec[BIAS::kNumChannels*2] = dUt;
391 vec[BIAS::kNumChannels*2+1] = fBiasOffset;
392
393 double avg[2] = { 0, 0 };
394 double min[2] = { 90, 90 };
395 double max[2] = { -90, -90 };
396 int num[2] = { 0, 0 };
397
398 vector<double> med[2];
399 med[0].resize(416);
400 med[1].resize(416);
401
402 if (fControlType==kCurrents)
403 {
404 if (fCursorCur==0)
405 {
406 //DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
407 return GetCurrentState();
408 }
409
410 // Pixel 583: 5 31 == 191 (5) C2 B3 P3
411 // Pixel 830: 2 2 == 66 (4) C0 B8 P1
412 // Pixel 1401: 6 1 == 193 (5) C2 B4 P0
413
414 // Convert from DAC counts to uA
415 const double conv = 5000./4096;
416
417 // 3900 Ohm/n + 1000 Ohm + 1100 Ohm (with n=4 or n=5)
418 const double R[2] = { 3075, 2870 };
419
420 const float *Iavg = fCalibration.data(); // Offset at U=fCalibrationOffset
421 const float *Ravg = fCalibration.data()+BIAS::kNumChannels*2; // Measured resistance
422
423 // U0 = fCalibrationOffset
424 // dT = fAppliedVoltage
425
426 // Ifeedback = Im[i] - (U[i]-U0)/Ravg[i] - Iavg[i];
427 // dUapplied[i] + dUneu[i] = R[g] * (Im[i] - (dUapplied[i]+dUneu[i]-U0+dT)/Ravg[i] - Iavg[i])
428
429 // The assumption here is that the offset calculated from the temperature
430 // does not significanly change within a single step
431
432 // dU[i] := dUtotal[i] = dUapplied[i] + dUneu[i]
433 // dU[i] / R[g] = Im[i] - (dU[i]+dT-U0)/Ravg[i] - Iavg[i]
434 // dU[i]/R[g] + dU[i]/Ravg[i] = Im[i] + U0/Ravg[i] - dT/Ravg[i] - Iavg[i]
435 // dU[i]*(1/R[g]+1/Ravg[i]) = Im[i] - Iavg[i] + U0/Ravg[i] - dT/Ravg[i]
436 // dU[i] = (Im[i] - Iavg[i] + U0/Ravg[i] - dT/Ravg[i]) / (1/R[g]+1/Ravg[i])
437 // dU[i] = { Im[i] - Iavg[i] + (U0-dT)/Ravg[i] } * r with r := 1 / (1/R[g]+1/Ravg[i])
438
439 const double U0 = fAppliedOffset-fCalibrationOffset;
440
441 for (int i=0; i<BIAS::kNumChannels; i++)
442 {
443 const PixelMapEntry &hv = fMap.hv(i);
444 if (!hv)
445 continue;
446
447 // Average measured current
448 const double Im = double(fCurrentsAvg[i])/fCursorCur * conv; // [uA]
449
450 // Group index (0 or 1) of the of the pixel (4 or 5 pixel patch)
451 const int g = hv.group();
452
453 // Serial resistors in front of the G-APD
454 double Rg = R[g];
455
456 // This is assuming that the broken pixels have a 390 Ohm instead of 3900 Ohm serial resistor
457 if (i==66) // Pixel 830(66)
458 Rg = 2400; // 2400 = (3/3900 + 1/390) + 1000 + 1100
459 if (i==191 || i==193) // Pixel 583(191) / Pixel 1401(193)
460 Rg = 2379; // 2379 = (4/3900 + 1/390) + 1000 + 1100
461
462 const double r = 1./(1./Rg + 1./Ravg[i]); // [Ohm]
463
464 // Offset induced by the voltage above the calibration point
465 const double dI = U0/Ravg[i]; // [V/Ohm]
466
467 // Offset at the calibration point (make sure that the calibration is
468 // valid (Im[i]>Iavg[i]) and we operate above the calibration point)
469 const double I = Im>Iavg[i] ? Im - Iavg[i] : 0; // [A]
470
471 // Make sure that the averaged resistor is valid
472 const double dU = Ravg[i]>10000 ? r*(I*1e-6 - dI) : 0;
473
474 vec[i+BIAS::kNumChannels] += dU;
475
476 // Angelegte Spannung: U0+dU
477 // Gemessener Strom: Im - Iavg
478 // Strom offset: (U0+dU) / Ravg
479 // Fliessender Strom: Im-Iavg - (U0+dU)/Ravg
480 // Korrektur: [ Im-Iavg - (U0+dU)/Ravg ] * Rg
481
482 // Aufgeloest nach dU: dU = ( Im-Iavg - dU/Ravg ) / ( 1/Rg + 1/Ravg )
483 // Equivalent zu: dU = ( I*Ravg - U0 ) / ( Ravg/Rg+1 )
484
485 // Calculate statistics only for channels with a valid calibration
486 if (Iavg[i]>0)
487 {
488 med[g][num[g]] = dU;
489 avg[g] += dU;
490 num[g]++;
491
492 if (dU<min[g])
493 min[g] = dU;
494 if (dU>max[g])
495 max[g] = dU;
496 }
497 }
498
499 sort(med[0].begin(), med[0].begin()+num[0]);
500 sort(med[1].begin(), med[1].begin()+num[1]);
501
502 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
503 fCursorCur = 0;
504 }
505
506 fDimDeviation.setQuality(fControlType);
507 fDimDeviation.Update(vec);
508
509 // Warning: Here it is assumed that the ramp up and down is done properly
510 // within the time between two new temperatures and that the calibration
511 // is finished within that time.
512 if (!(GetCurrentState()==Feedback::State::kCalibrating && fCursorTemp==1 && fOutputEnabled && fDimBias.state()==BIAS::State::kVoltageOff))
513 {
514 if (!fOutputEnabled || fDimBias.state()!=BIAS::State::kVoltageOn)
515 return GetCurrentState();
516
517 // Trigger calibration
518 if (GetCurrentState()==Feedback::State::kCalibrating && fCursorTemp==2)
519 {
520 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
521 return GetCurrentState();
522 }
523 }
524
525 ostringstream msg;
526 msg << setprecision(4) << "Sending new absolute offset (" << fAppliedOffset << "V+" << (num[0]+num[1]>0?(avg[0]+avg[1])/(num[0]+num[1]):0) << "V) to biasctrl.";
527 Info(msg);
528
529 if (fControlType==kCurrents && num[0]>0 && num[1]>0)
530 {
531 msg.str("");
532 msg << " Avg0=" << setw(7) << avg[0]/num[0] << " | Avg1=" << setw(7) << avg[1]/num[1];
533 Debug(msg);
534
535 msg.str("");
536 msg << " Med0=" << setw(7) << med[0][num[0]/2] << " | Med1=" << setw(7) << med[1][num[1]/2];
537 Debug(msg);
538
539 msg.str("");
540 msg << " Min0=" << setw(7) << min[0] << " | Min1=" << setw(7) << min[1];
541 Debug(msg);
542
543 msg.str("");
544 msg << " Max0=" << setw(7) << max[0] << " | Max1=" << setw(7) << max[1];
545 Debug(msg);
546 }
547
548 DimClient::sendCommandNB("BIAS_CONTROL/SET_ALL_CHANNELS_OFFSET",
549 vec.data()+BIAS::kNumChannels, BIAS::kNumChannels*sizeof(float));
550
551 return GetCurrentState();
552 }
553
554 int AverageCurrents(const EventImp &evt)
555 {
556 if (evt.GetSize()!=BIAS::kNumChannels*sizeof(int16_t))
557 return -1;
558
559 if (fDimBias.state()!=BIAS::State::kVoltageOn)
560 return false;
561
562 if (fCursorCur++<0)
563 return true;
564
565 const int16_t *ptr = evt.Ptr<int16_t>();
566
567 for (int i=0; i<BIAS::kNumChannels; i++)
568 {
569 fCurrentsAvg[i] += ptr[i];
570 fCurrentsRms[i] += ptr[i]*ptr[i];
571 }
572
573 return true;
574 }
575
576
577 void HandleCalibration(const EventImp &evt)
578 {
579 const int rc = AverageCurrents(evt);
580 if (rc<0)
581 return;
582
583 if (fCursorCur<fNumCalibRequests)
584 {
585 if (fDimBias.state()==BIAS::State::kVoltageOn)
586 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
587 return;
588 }
589
590 if (rc==0)
591 return;
592
593 fCalibration.resize(BIAS::kNumChannels*3);
594
595 float *avg = fCalibration.data();
596 float *rms = fCalibration.data()+BIAS::kNumChannels;
597 float *res = fCalibration.data()+BIAS::kNumChannels*2;
598
599 const double conv = 5000./4096;
600
601 for (int i=0; i<BIAS::kNumChannels; i++)
602 {
603 const double I = double(fCurrentsAvg[i])/fCursorCur;
604
605 res[i] = (fVoltGapd[i]+fCalibrationOffset)/I / conv * 1e6;
606 avg[i] = conv * I;
607 rms[i] = conv * sqrt(double(fCurrentsRms[i])/fCursorCur-I*I);
608 }
609
610 fCalibTime = Time();
611
612 fDimCalibration.setData(fCalibration);
613 fDimCalibration.Update(fCalibTime);
614
615 fOutputEnabled = false;
616 fControlType = kIdle;
617
618 Info("Calibration successfully done.");
619
620 if (fDimBias.state()==BIAS::State::kVoltageOn)
621 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
622 }
623
624 void HandleFeedback(const EventImp &evt)
625 {
626 if (evt.GetSize()!=1440*sizeof(float))
627 return;
628
629 // -------- Check age of last stored event --------
630
631 const Time tm(evt.GetTime());
632
633 if (Time()-fBiasLast>boost::posix_time::seconds(30))
634 {
635 Warn("Last received event data older than 30s... resetting average calculation.");
636 ResetData();
637 }
638 fBiasLast = tm;
639
640 // -------- Store new event --------
641
642 fData[fCursorAmpl%fData.size()].assign(evt.Ptr<float>(), evt.Ptr<float>()+1440);
643 if (++fCursorAmpl<fData.size())
644 return;
645
646 // -------- Calculate statistics --------
647
648 valarray<double> med(1440);
649
650 for (int ch=0; ch<1440; ch++)
651 {
652 vector<float> arr(fData.size());
653 for (size_t i=0; i<fData.size(); i++)
654 arr[i] = fData[i][ch];
655
656 sort(arr.begin(), arr.end());
657
658 med[ch] = arr[arr.size()/2];
659 }
660
661 /*
662 vector<float> med(1440);
663 vector<float> rms(1440);
664 for (size_t i=0; i<fData.size(); i++)
665 {
666 if (fData[i].size()==0)
667 return;
668
669 for (int j=0; j<1440; j++)
670 {
671 med[j] += fData[i][j];
672 rms[j] += fData[i][j]*fData[i][j];
673 }
674 }
675 */
676
677 vector<double> avg(BIAS::kNumChannels);
678 vector<int> num(BIAS::kNumChannels);
679 for (int i=0; i<1440; i++)
680 {
681 const PixelMapEntry &ch = fMap.hw(i);
682
683 // FIXME: Add a consistency check if the median makes sense...
684 // FIXME: Add a consistency check to remove pixels with bright stars (median?)
685
686 avg[ch.hv()] += med[i];
687 num[ch.hv()]++;
688 }
689
690 for (int i=0; i<BIAS::kNumChannels; i++)
691 {
692 if (num[i])
693 avg[i] /= num[i];
694
695 }
696
697 // -------- Calculate correction --------
698
699 // http://bestune.50megs.com/typeABC.htm
700
701 // CO: Controller output
702 // PV: Process variable
703 // SP: Set point
704 // T: Sampling period (loop update period)
705 // e = SP - PV
706 //
707 // Kp : No units
708 // Ki : per seconds
709 // Kd : seconds
710
711 // CO(k)-CO(k-1) = - Kp[ PV(k) - PV(k-1) ] + Ki * T * (SP(k)-PV(k)) - Kd/T [ PV(k) - 2PV(k-1) + PV(k-2) ]
712
713 if (fCursorAmpl%fData.size()>0)
714 return;
715
716 // FIXME: Take out broken / dead boards.
717
718 const Time tm0 = Time();
719
720 /*const*/ double T21 = fT>0 ? fT : (tm0-fStartTime).total_microseconds()/1000000.;
721 const double T10 = fT21;
722 fT21 = T21;
723
724 fStartTime = tm0;
725
726 ostringstream out;
727 out << "New " << fData.size() << " event received: " << fCursorAmpl << " / " << setprecision(3) << T21 << "s";
728 Info(out);
729
730 if (fPV[0].size()==0)
731 {
732 fPV[0].resize(avg.size());
733 fPV[0] = valarray<double>(avg.data(), avg.size());
734 return;
735 }
736
737 if (fPV[1].size()==0)
738 {
739 fPV[1].resize(avg.size());
740 fPV[1] = valarray<double>(avg.data(), avg.size());
741 return;
742 }
743
744 if (fPV[2].size()==0)
745 {
746 fPV[2].resize(avg.size());
747 fPV[2] = valarray<double>(avg.data(), avg.size());
748 return;
749 }
750
751 fPV[0] = fPV[1];
752 fPV[1] = fPV[2];
753
754 fPV[2].resize(avg.size());
755 fPV[2] = valarray<double>(avg.data(), avg.size());
756
757 if (T10<=0 || T21<=0)
758 return;
759
760 //cout << "Calculating (" << fCursor << ":" << T21 << ")... " << endl;
761
762 // fKi[j] = response[j]*gain;
763 // Kp = 0;
764 // Kd = 0;
765
766 // => Kp = 0.01 * gain = 0.00005
767 // => Ki = 0.8 * gain/20s = 0.00025
768 // => Kd = 0.1 * gain/20s = 0.00003
769
770 /*
771 fKp = 0;
772 fKd = 0;
773 fKi = 0.00003*20;
774 T21 = 1;
775 */
776
777 //valarray<double> correction = - Kp*(PV[2] - PV[1]) + Ki * dT * (SP-PV[2]) - Kd/dT * (PV[2] - 2*PV[1] + PV[0]);
778 //valarray<double> correction =
779 // - Kp * (PV[2] - PV[1])
780 // + dT * Ki * (SP - PV[2])
781 // - Kd / dT * (PV[2] - 2*PV[1] + PV[0]);
782 //
783 // - (Kp+Kd/dT1) * (PV[2] - PV[1])
784 // + dT2 * Ki * (SP - PV[2])
785 // + Kd / dT1 * (PV[1] - PV[0]);
786 //
787 // - Kp * (PV[2] - PV[1])
788 // + Ki * (SP - PV[2])*dT
789 // - Kd * (PV[2] - PV[1])/dT
790 // + Kd * (PV[1] - PV[0])/dT;
791 //
792 //valarray<double> correction =
793 // - Kp*(PV[2] - PV[1]) + Ki * T21 * (SP-PV[2]) - Kd*(PV[2]-PV[1])/T21 - Kd*(PV[0]-PV[1])/T01;
794 const valarray<double> correction = 1./fGain/1000*
795 (
796 - (fKp+fKd/T21)*(fPV[2] - fPV[1])
797 + fKi*T21*(fSP-fPV[2])
798 + fKd/T10*(fPV[1]-fPV[0])
799 );
800
801 /*
802 integral = 0
803 start:
804 integral += (fSP - fPV[2])*dt
805
806 output = Kp*(fSP - fPV[2]) + Ki*integral - Kd*(fPV[2] - fPV[1])/dt
807
808 wait(dt)
809
810 goto start
811 */
812
813 vector<float> vec(2*BIAS::kNumChannels+2);
814 for (int i=0; i<BIAS::kNumChannels; i++)
815 vec[i] = fPV[2][i]-fSP[i];
816
817 for (int i=0; i<BIAS::kNumChannels; i++)
818 vec[i+BIAS::kNumChannels] = avg[i]<5*2.5 ? 0 : correction[i];
819
820 fDimDeviation.setQuality(fControlType);
821 fDimDeviation.Update(vec);
822
823 if (!fOutputEnabled || fDimBias.state()!=BIAS::State::kVoltageOn)
824 return;
825
826 Info("Sending new relative offset to biasctrl.");
827
828 DimClient::sendCommandNB("BIAS_CONTROL/INCREASE_ALL_CHANNELS_VOLTAGE",
829 vec.data()+BIAS::kNumChannels, BIAS::kNumChannels*sizeof(float));
830 }
831
832 void HandleGlobalFeedback(const EventImp &evt)
833 {
834 if (evt.GetSize()!=1440*sizeof(float))
835 return;
836
837 // -------- Store new event --------
838
839 vector<float> arr(evt.Ptr<float>(), evt.Ptr<float>()+1440);
840
841 sort(arr.begin(), arr.end());
842
843 const float med = arr[arr.size()/2];
844
845 fData[fCursorAmpl%fData.size()].resize(1); //assign(&med, &med);
846 fData[fCursorAmpl%fData.size()][0] = med; //assign(&med, &med);
847
848 if (++fCursorAmpl<fData.size())
849 return;
850
851 // -------- Calculate statistics --------
852
853 double avg=0;
854 double rms=0;
855 for (size_t i=0; i<fData.size(); i++)
856 {
857 avg += fData[i][0];
858 rms += fData[i][0]*fData[i][0];
859 }
860
861 avg /= fData.size();
862 rms /= fData.size();
863
864 rms = sqrt(rms-avg*avg);
865
866 // -------- Calculate correction --------
867
868 if (fCursorAmpl%fData.size()!=0)
869 return;
870
871 Out() << "Amplitude: " << avg << " +- " << rms << endl;
872
873 // FIXME: Take out broken / dead boards.
874
875 /*
876 ostringstream out;
877 out << "New " << fData.size() << " event received: " << fCursor << " / " << setprecision(3) << T21 << "s";
878 Info(out);
879 */
880
881 if (fPV[0].size()==0)
882 {
883 fPV[0].resize(1);
884 fPV[0] = valarray<double>(&avg, 1);
885 return;
886 }
887
888 if (fPV[1].size()==0)
889 {
890 fPV[1].resize(1);
891 fPV[1] = valarray<double>(&avg, 1);
892 return;
893 }
894
895 if (fPV[2].size()==0)
896 {
897 fPV[2].resize(1);
898 fPV[2] = valarray<double>(&avg, 1);
899 return;
900 }
901
902 fPV[0] = fPV[1];
903 fPV[1] = fPV[2];
904
905 fPV[2].resize(1);
906 fPV[2] = valarray<double>(&avg, 1);
907
908 // ----- Calculate average currents -----
909
910 vector<float> A(BIAS::kNumChannels);
911 for (int i=0; i<BIAS::kNumChannels; i++)
912 A[i] = double(fCurrentsAvg[i]) / fCursorCur;
913
914 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
915 fCursorCur = 0;
916
917 // -------- Calculate correction --------
918
919 // correction = (fSP[0]-fPV[2])*fKi
920 /*
921 const double T21 = 1; // feedback is 1s
922 const double T10 = 1; // feedback is 20s
923
924 const valarray<double> correction = 1./fGain/1000*
925 (
926 - (fKp+fKd/T21)*(fPV[2] - fPV[1])
927 + fKi*T21*(fSP[0]-fPV[2])
928 + fKd/T10*(fPV[1]-fPV[0])
929 );
930 */
931
932 // pow of 1.6 comes from the non-linearity of the
933 // amplitude vs bias voltage
934 const valarray<double> correction = 1./fGain/1000*
935 (
936 //fKi*(pow(fSP[0], 1./1.6)-pow(fPV[2], 1./1.6))
937 fKi*(fSP[0]-fPV[2])
938 );
939
940 Out() << "Correction: " << correction[0] << "V (" << fSP[0] << ")" << endl;
941
942 const int nch = BIAS::kNumChannels;
943
944 // FIXME: Sanity check!
945
946 vector<float> vec;
947 vec.reserve(2*nch+2);
948 vec.insert(vec.begin(), nch, fPV[2][0]-fSP[0]);
949 vec.insert(vec.begin()+nch, nch, correction[0]);
950 vec.push_back(0);
951 vec.push_back(0);
952
953 fDimDeviation.setQuality(fControlType);
954 fDimDeviation.Update(vec);
955
956 if (!fOutputEnabled || fDimBias.state()!=BIAS::State::kVoltageOn)
957 return;
958
959 Info("Sending new global relative offset to biasctrl.");
960
961 DimClient::sendCommandNB("BIAS_CONTROL/INCREASE_ALL_CHANNELS_VOLTAGE",
962 vec.data()+BIAS::kNumChannels, BIAS::kNumChannels*sizeof(float));
963 }
964
965 void HandleCalibrateCurrents(const EventImp &evt)
966 {
967 if (fBiasVolt.empty() || fCalibration.empty() || evt.GetSize()<416*sizeof(int16_t))
968 return;
969
970 struct dim_data {
971 float I[416];
972 float Iavg;
973 float Irms;
974 float Imed;
975 float Idev;
976 uint32_t N;
977 float Tdiff;
978
979 dim_data() { memset(this, 0, sizeof(dim_data)); }
980 } __attribute__((__packed__));
981
982 const int16_t *I = evt.Ptr<int16_t>();
983 const float *R = fCalibration.data()+BIAS::kNumChannels*2;
984 const float *U = fBiasVolt.data();
985
986 vector<float> med(416);
987 uint16_t cnt = 0;
988
989 double avg = 0;
990 double rms = 0;
991
992 dim_data data;
993 for (int i=0; i<416; i++)
994 {
995 const PixelMapEntry &hv = fMap.hv(i);
996 if (!hv)
997 continue;
998
999 if (R[i]<=0)
1000 continue;
1001
1002 data.I[i] = I[i]*5000./4096 - U[i]/R[i]*1e6;
1003 data.I[i] /= hv.group() ? 5 : 4;
1004
1005 avg += data.I[i];
1006 rms += data.I[i]*data.I[i];
1007
1008 if (i>=320)
1009 continue;
1010
1011 med[cnt++] = data.I[i];
1012 }
1013
1014 if (cnt==0)
1015 return;
1016
1017 avg /= cnt;
1018 rms /= cnt;
1019
1020 data.N = cnt;
1021 data.Iavg = avg;
1022 data.Irms = sqrt(rms-avg*avg);
1023
1024 sort(med.data(), med.data()+cnt);
1025
1026 data.Imed = cnt%2 ? (med[cnt/2-1]+med[cnt/2])/2 : med[cnt/2];
1027
1028 for (int i=0; i<cnt; i++)
1029 med[i] = fabs(med[i]-data.Imed);
1030
1031 sort(med.data(), med.data()+cnt);
1032
1033 data.Idev = med[uint32_t(0.682689477208650697*cnt)];
1034
1035 data.Tdiff = evt.GetTime().UnixTime()-fCalibTime.UnixTime();
1036
1037 fDimCurrents.setData(&data, sizeof(dim_data));
1038 fDimCurrents.Update(evt.GetTime());
1039 }
1040
1041 int HandleBiasCurrent(const EventImp &evt)
1042 {
1043 if (fControlType==kTemp && GetCurrentState()==Feedback::State::kCalibrating)
1044 HandleCalibration(evt);
1045
1046 if (fControlType==kFeedbackGlobal || fControlType==kCurrents || fControlType==kCurrentsNew)
1047 AverageCurrents(evt);
1048
1049 /*
1050 if (fControlType==kCurrents && fCursorTemp>0 && fCursorCur>0)
1051 {
1052 // fCursorTemp: 1 2 3 4 5 6 7 8
1053 // fCursor%x: 1 1 1 2 2 2 3 3 // 9 steps in ~15s
1054 //if (fCursorTemp<3 && fCursorCur%(fCursorTemp/3+1)==0)
1055 HandleCurrentControl();
1056 }*/
1057
1058 HandleCalibrateCurrents(evt);
1059
1060 return GetCurrentState();
1061 }
1062
1063 int HandleBiasData(const EventImp &evt)
1064 {
1065 if (fControlType==kFeedback)
1066 HandleFeedback(evt);
1067
1068 if (fControlType==kFeedbackGlobal)
1069 HandleGlobalFeedback(evt);
1070
1071 return GetCurrentState();
1072 }
1073
1074 int HandleBiasNom(const EventImp &evt)
1075 {
1076 if (evt.GetSize()>=416*sizeof(float))
1077 {
1078 fVoltGapd.assign(evt.Ptr<float>(), evt.Ptr<float>()+416);
1079 Info("Nominal bias voltages received.");
1080 }
1081
1082 return GetCurrentState();
1083 }
1084
1085 int HandleBiasVoltage(const EventImp &evt)
1086 {
1087 if (evt.GetSize()>=416*sizeof(float))
1088 fBiasVolt.assign(evt.Ptr<float>(), evt.Ptr<float>()+416);
1089 return GetCurrentState();
1090 }
1091
1092 bool CheckEventSize(size_t has, const char *name, size_t size)
1093 {
1094 if (has==size)
1095 return true;
1096
1097 ostringstream msg;
1098 msg << name << " - Received event has " << has << " bytes, but expected " << size << ".";
1099 Fatal(msg);
1100 return false;
1101 }
1102
1103 int Print() const
1104 {
1105 Out() << fDim << endl;
1106 Out() << fDimFAD << endl;
1107 Out() << fDimFSC << endl;
1108 Out() << fDimBias << endl;
1109
1110 return GetCurrentState();
1111 }
1112
1113 int PrintCalibration()
1114 {
1115 if (fCalibration.empty())
1116 {
1117 Out() << "No calibration performed so far." << endl;
1118 return GetCurrentState();
1119 }
1120
1121 const float *avg = fCalibration.data();
1122 const float *rms = fCalibration.data()+BIAS::kNumChannels;
1123 const float *res = fCalibration.data()+BIAS::kNumChannels*2;
1124
1125 Out() << "Average current at " << fCalibrationOffset << "V below G-APD operation voltage:\n";
1126
1127 for (int k=0; k<13; k++)
1128 for (int j=0; j<8; j++)
1129 {
1130 Out() << setw(2) << k << "|" << setw(2) << j*4 << "|";
1131 for (int i=0; i<4; i++)
1132 Out() << Tools::Form(" %6.1f+-%4.1f", avg[k*32+j*4+i], rms[k*32+j*4+i]);
1133 Out() << '\n';
1134 }
1135 Out() << '\n';
1136
1137 Out() << "Measured calibration resistor:\n";
1138 for (int k=0; k<13; k++)
1139 for (int j=0; j<4; j++)
1140 {
1141 Out() << setw(2) << k << "|" << setw(2) << j*8 << "|";
1142 for (int i=0; i<8; i++)
1143 Out() << Tools::Form(" %5.0f", res[k*32+j*8+i]);
1144 Out() << '\n';
1145 }
1146
1147 Out() << flush;
1148
1149 return GetCurrentState();
1150 }
1151
1152 void WarnState(bool needfsc, bool needfad)
1153 {
1154 const bool bias = fDimBias.state() >= BIAS::State::kConnecting;
1155 const bool fsc = fDimFSC.state() >= FSC::State::kConnected;
1156 const bool fad = fDimFAD.state() >= FAD::State::kConnected;
1157
1158 if (!bias)
1159 Warn("Bias control not yet ready.");
1160 if (needfsc && !fsc)
1161 Warn("FSC control not yet ready.");
1162 if (needfad && !fad)
1163 Warn("FAD control not yet ready.");
1164 }
1165
1166 int SetConstant(const EventImp &evt, int constant)
1167 {
1168 if (!CheckEventSize(evt.GetSize(), "SetConstant", 8))
1169 return kSM_FatalError;
1170
1171 switch (constant)
1172 {
1173 case 0: fKi = evt.GetDouble(); break;
1174 case 1: fKp = evt.GetDouble(); break;
1175 case 2: fKd = evt.GetDouble(); break;
1176 case 3: fT = evt.GetDouble(); break;
1177 case 4: fGain = evt.GetDouble(); break;
1178 default:
1179 Fatal("SetConstant got an unexpected constant id -- this is a program bug!");
1180 return kSM_FatalError;
1181 }
1182
1183 return GetCurrentState();
1184 }
1185
1186 int EnableOutput(const EventImp &evt)
1187 {
1188 if (!CheckEventSize(evt.GetSize(), "EnableOutput", 1))
1189 return kSM_FatalError;
1190
1191 fOutputEnabled = evt.GetBool();
1192
1193 if (fControlType==kCurrents || fControlType==kCurrentsNew)
1194 if (fCursorTemp>1)
1195 fCursorTemp = 1;
1196
1197 return GetCurrentState();
1198 }
1199
1200 void ResetData(int16_t n=-1)
1201 {
1202 fData.assign(n>0 ? n : fData.size(), vector<float>(0));
1203
1204 fCursorAmpl = 0;
1205 fCursorCur = 0;
1206 fCursorTemp = 0;
1207
1208 fStartTime = Time();
1209
1210 fSP = valarray<double>(0., BIAS::kNumChannels);
1211
1212 vector<float> vec(2*BIAS::kNumChannels+2, fBiasOffset);
1213 vec[2*BIAS::kNumChannels] = 0;
1214 fDimDeviation.setQuality(kIdle);
1215 fDimDeviation.Update(vec);
1216
1217 fPV[0].resize(0);
1218 fPV[1].resize(0);
1219 fPV[2].resize(0);
1220
1221 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
1222 fCurrentsRms.assign(BIAS::kNumChannels, 0);
1223
1224 if (fKp==0 && fKi==0 && fKd==0)
1225 Warn("Control loop parameters are all set to zero.");
1226 }
1227
1228 int StartFeedback(const EventImp &evt)
1229 {
1230 if (!CheckEventSize(evt.GetSize(), "StartFeedback", 2))
1231 return kSM_FatalError;
1232
1233 WarnState(false, true);
1234
1235 fBiasOffset = 0;
1236 ResetData(evt.GetShort());
1237
1238 fControlType = kFeedback;
1239
1240 return GetCurrentState();
1241 }
1242
1243 int StartFeedbackGlobal(const EventImp &evt)
1244 {
1245 if (!CheckEventSize(evt.GetSize(), "StartFeedbackGlobal", 2))
1246 return kSM_FatalError;
1247
1248 WarnState(false, true);
1249
1250 fBiasOffset = 0;
1251 ResetData(evt.GetShort());
1252
1253 fControlType = kFeedbackGlobal;
1254
1255 return GetCurrentState();
1256 }
1257
1258 int StartTempCtrl(const EventImp &evt)
1259 {
1260 if (!CheckEventSize(evt.GetSize(), "StartTempCtrl", 4))
1261 return kSM_FatalError;
1262
1263 WarnState(true, false);
1264
1265 fBiasOffset = evt.GetFloat();
1266 fControlType = kTemp;
1267
1268 ostringstream out;
1269 out << "Starting temperature feedback with an offset of " << fBiasOffset << "V";
1270 Message(out);
1271
1272 if (fDimBias.state()==BIAS::State::kVoltageOn)
1273 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
1274
1275 return GetCurrentState();
1276 }
1277
1278 int StartCurrentCtrl(const EventImp &evt)
1279 {
1280 if (!CheckEventSize(evt.GetSize(), "StartCurrentCtrl", 4))
1281 return kSM_FatalError;
1282
1283 if (fCalibration.empty())
1284 {
1285 Warn("Current control needs a bias crate calibration first... command ignored.");
1286 return GetCurrentState();
1287 }
1288
1289 WarnState(true, false);
1290
1291 fBiasOffset = evt.GetFloat();
1292 fTempOffset = -3;
1293 ResetData(0);
1294 fControlType = kCurrents;
1295
1296 ostringstream out;
1297 out << "Starting current/temp feedback with an offset of " << fBiasOffset << "V";
1298 Message(out);
1299
1300 return GetCurrentState();
1301 }
1302
1303 int StartNewCurrentCtrl(const EventImp &evt)
1304 {
1305 if (!CheckEventSize(evt.GetSize(), "StartNewCurrentCtrl", 4))
1306 return kSM_FatalError;
1307
1308 if (fCalibration.empty())
1309 {
1310 Warn("Current control needs a bias crate calibration first... command ignored.");
1311 return GetCurrentState();
1312 }
1313
1314 WarnState(true, false);
1315
1316 fBiasOffset = evt.GetFloat();
1317 fTempOffset = -3;
1318 ResetData(0);
1319 fControlType = kCurrentsNew;
1320
1321 ostringstream out;
1322 out << "Starting new current/temp feedback with an offset of " << fBiasOffset << "V";
1323 Message(out);
1324
1325 return GetCurrentState();
1326 }
1327
1328 int StopFeedback()
1329 {
1330 fControlType = kIdle;
1331
1332 return GetCurrentState();
1333 }
1334
1335 int StoreReference()
1336 {
1337 if (!fPV[0].size() && !fPV[1].size() && !fPV[2].size())
1338 {
1339 Warn("No values in memory. Take enough events first!");
1340 return GetCurrentState();
1341 }
1342
1343 // FIXME: Check age
1344
1345 if (!fPV[1].size() && !fPV[2].size())
1346 fSP = fPV[0];
1347
1348 if (!fPV[2].size())
1349 fSP = fPV[1];
1350 else
1351 fSP = fPV[2];
1352
1353 vector<float> vec(BIAS::kNumChannels);
1354 for (int i=0; i<BIAS::kNumChannels; i++)
1355 vec[i] = fSP[i];
1356 fDimReference.Update(vec);
1357
1358 return GetCurrentState();
1359 }
1360
1361 int SetReference(const EventImp &evt)
1362 {
1363 if (!CheckEventSize(evt.GetSize(), "SetReference", 4))
1364 return kSM_FatalError;
1365
1366 const float val = evt.GetFloat();
1367 /*
1368 if (!fPV[0].size() && !fPV[1].size() && !fPV[2].size())
1369 {
1370 Warn("No values in memory. Take enough events first!");
1371 return GetCurrentState();
1372 }*/
1373
1374 vector<float> vec(BIAS::kNumChannels);
1375 for (int i=0; i<BIAS::kNumChannels; i++)
1376 vec[i] = fSP[i] = val;
1377 fDimReference.Update(vec);
1378
1379 Out() << "New global reference value: " << val << "mV" << endl;
1380
1381 return GetCurrentState();
1382 }
1383
1384 int CalibrateCurrents()
1385 {
1386// if (!CheckEventSize(evt.GetSize(), "StartTempCtrl", 4))
1387// return kSM_FatalError;
1388
1389 if (fDimBias.state()==BIAS::State::kRamping)
1390 {
1391 Warn("Calibration cannot be started when biasctrl is in state Ramping.");
1392 return GetCurrentState();
1393 }
1394
1395 if (fVoltGapd.empty())
1396 {
1397 Error("No G-APD reference voltages received yet (BIAS_CONTROL/NOMINAL).");
1398 return GetCurrentState();
1399 }
1400
1401 WarnState(true, false);
1402
1403 ostringstream out;
1404 out << "Starting temperature feedback for calibration with an offset of " << fCalibrationOffset << "V";
1405 Message(out);
1406
1407 fBiasOffset = fCalibrationOffset;
1408 fControlType = kTemp;
1409 fCursorCur = -fNumCalibIgnore;
1410 fCursorTemp = 0;
1411 fCurrentsAvg.assign(BIAS::kNumChannels, 0);
1412 fCurrentsRms.assign(BIAS::kNumChannels, 0);
1413 fCalibration.resize(0);
1414 fStartTime = Time();
1415 fOutputEnabled = true;
1416
1417 return Feedback::State::kCalibrating;
1418 }
1419
1420 int SetCurrentRequestInterval(const EventImp &evt)
1421 {
1422 if (!CheckEventSize(evt.GetSize(), "SetCurrentRequestInterval", 2))
1423 return kSM_FatalError;
1424
1425 fCurrentRequestInterval = evt.GetUShort();
1426
1427 Out() << "New current request interval: " << fCurrentRequestInterval << "ms" << endl;
1428
1429 return GetCurrentState();
1430 }
1431
1432 int Execute()
1433 {
1434 // Dispatch (execute) at most one handler from the queue. In contrary
1435 // to run_one(), it doesn't wait until a handler is available
1436 // which can be dispatched, so poll_one() might return with 0
1437 // handlers dispatched. The handlers are always dispatched/executed
1438 // synchronously, i.e. within the call to poll_one()
1439 //poll_one();
1440
1441 if (!fDim.online())
1442 return Feedback::State::kDimNetworkNA;
1443
1444 const bool bias = fDimBias.state() >= BIAS::State::kConnecting;
1445 const bool fad = fDimFAD.state() >= FAD::State::kConnected;
1446 const bool fsc = fDimFSC.state() >= FSC::State::kConnected;
1447
1448 // All subsystems are not connected
1449 if (!bias && !fad && !fsc)
1450 return Feedback::State::kDisconnected;
1451
1452 // At least one subsystem apart from bias is connected
1453 if (bias && !fad && !fsc)
1454 return Feedback::State::kConnecting;
1455
1456/*
1457 // All subsystems are connected
1458 if (GetCurrentStatus()==Feedback::State::kConfiguringStep1)
1459 {
1460 if (fCursor<1)
1461 return Feedback::State::kConfiguringStep1;
1462
1463 if (fCursor==1)
1464 {
1465 fStartTime = Time();
1466 return Feedback::State::kConfiguringStep2;
1467 }
1468 }
1469 if (GetCurrentStatus()==Feedback::State::kConfiguringStep2)
1470 {
1471 if (fCursor==1)
1472 {
1473 if ((Time()-fStartTime).total_microseconds()/1000000.<1.5)
1474 return Feedback::State::kConfiguringStep2;
1475
1476 Dim::SendCommand("BIAS_CONTROL/REQUEST_STATUS");
1477 }
1478 if (fCursor==2)
1479 {
1480
1481 int n=0;
1482 double avg = 0;
1483 for (size_t i=0; i<fCurrents.size(); i++)
1484 if (fCurrents[i]>=0)
1485 {
1486 avg += fCurrents[i];
1487 n++;
1488 }
1489
1490 cout << avg/n << endl;
1491 }
1492 return Feedback::State::kConnected;
1493 }
1494 */
1495
1496 // Needs connection of FAD and BIAS
1497 if (bias && fad)
1498 {
1499 if (fControlType==kFeedback || fControlType==kFeedbackGlobal)
1500 return fOutputEnabled ? Feedback::State::kFeedbackCtrlRunning : Feedback::State::kFeedbackCtrlIdle;
1501 }
1502
1503 // Needs connection of FSC and BIAS
1504 if (bias && fsc)
1505 {
1506 if (fControlType==kTemp)
1507 {
1508 if (GetCurrentState()==Feedback::State::kCalibrating && fCursorCur<fNumCalibRequests)
1509 return GetCurrentState();
1510
1511 return fOutputEnabled ? Feedback::State::kTempCtrlRunning : Feedback::State::kTempCtrlIdle;
1512 }
1513 if (fControlType==kCurrents || fControlType==kCurrentsNew)
1514 {
1515 static Time past;
1516 if (fCurrentRequestInterval>0 && Time()-past>boost::posix_time::milliseconds(fCurrentRequestInterval))
1517 {
1518 if (fDimBias.state()==BIAS::State::kVoltageOn)
1519 DimClient::sendCommandNB("BIAS_CONTROL/REQUEST_STATUS", NULL, 0);
1520 past = Time();
1521 }
1522
1523 return fOutputEnabled && fCursorTemp>0 ? Feedback::State::kCurrentCtrlRunning : Feedback::State::kCurrentCtrlIdle;
1524 }
1525 }
1526
1527 if (bias && fad && !fsc)
1528 return Feedback::State::kConnectedFAD;
1529
1530 if (bias && fsc && !fad)
1531 return Feedback::State::kConnectedFSC;
1532
1533 return Feedback::State::kConnected;
1534 }
1535
1536public:
1537 StateMachineFeedback(ostream &out=cout) : StateMachineDim(out, "FEEDBACK"),
1538 //---
1539 fDimFAD("FAD_CONTROL"),
1540 fDimFSC("FSC_CONTROL"),
1541 fDimBias("BIAS_CONTROL"),
1542 //---
1543 fDimReference("FEEDBACK/REFERENCE", "F:416",
1544 "Amplitude reference value(s)"
1545 "Vref[mV]:Amplitude reference"),
1546 fDimDeviation("FEEDBACK/DEVIATION", "F:416;F:416;F:1;F:1",
1547 "Control loop information"
1548 "|DeltaAmpl[mV]:Amplitude offset measures"
1549 "|DeltaBias[mV]:Correction value calculated"
1550 "|DeltaTemp[mV]:Correction calculated from temperature"
1551 "|DeltaUser[mV]:Additional offset specified by user"),
1552 fDimCalibration("FEEDBACK/CALIBRATION", "F:416;F:416;F:416",
1553 "Current offsets"
1554 "|Avg[uA]:Average offset"
1555 "|Rms[uA]:Rms of offset"
1556 "|R[Ohm]:Measured calibration resistor"),
1557 fDimCurrents("FEEDBACK/CALIBRATED_CURRENTS", "F:416;F:1;F:1;F:1;F:1;I:1;F:1",
1558 "Calibrated currents"
1559 "|I[uA]:Calibrated currents"
1560 "|I_avg[uA]:Average calibrated current (320 channels)"
1561 "|I_rms[uA]:Rms of calibrated current (320 channels)"
1562 "|I_med[uA]:Median calibrated current (320 channels)"
1563 "|I_dev[uA]:Deviation of calibrated current (320 channels)"
1564 "|N[uint16]:Number of valid values"
1565 "|T_diff[s]:Time difference to calibration"),
1566 fSP(BIAS::kNumChannels),
1567 fKp(0), fKi(0), fKd(0), fT(-1),
1568 fCalibrationOffset(-3),
1569 fCurrentRequestInterval(0),
1570 fNumCalibIgnore(30),
1571 fNumCalibRequests(300),
1572 fOutputEnabled(false)
1573 {
1574 // ba::io_service::work is a kind of keep_alive for the loop.
1575 // It prevents the io_service to go to stopped state, which
1576 // would prevent any consecutive calls to run()
1577 // or poll() to do nothing. reset() could also revoke to the
1578 // previous state but this might introduce some overhead of
1579 // deletion and creation of threads and more.
1580
1581 fDim.Subscribe(*this);
1582 fDimFAD.Subscribe(*this);
1583 fDimFSC.Subscribe(*this);
1584 fDimBias.Subscribe(*this);
1585
1586 Subscribe("BIAS_CONTROL/CURRENT")
1587 (bind(&StateMachineFeedback::HandleBiasCurrent, this, placeholders::_1));
1588 Subscribe("BIAS_CONTROL/VOLTAGE")
1589 (bind(&StateMachineFeedback::HandleBiasVoltage, this, placeholders::_1));
1590 Subscribe("BIAS_CONTROL/FEEDBACK_DATA")
1591 (bind(&StateMachineFeedback::HandleBiasData, this, placeholders::_1));
1592 Subscribe("BIAS_CONTROL/NOMINAL")
1593 (bind(&StateMachineFeedback::HandleBiasNom, this, placeholders::_1));
1594 Subscribe("FSC_CONTROL/TEMPERATURE")
1595 (bind(&StateMachineFeedback::HandleCameraTemp, this, placeholders::_1));
1596
1597 // State names
1598 AddStateName(Feedback::State::kDimNetworkNA, "DimNetworkNotAvailable",
1599 "The Dim DNS is not reachable.");
1600
1601 AddStateName(Feedback::State::kDisconnected, "Disconnected",
1602 "The Dim DNS is reachable, but the required subsystems are not available.");
1603
1604 AddStateName(Feedback::State::kConnecting, "Connecting",
1605 "Only biasctrl is available and connected with its hardware.");
1606
1607 AddStateName(Feedback::State::kConnectedFSC, "ConnectedFSC",
1608 "biasctrl and fscctrl are available and connected with their hardware.");
1609 AddStateName(Feedback::State::kConnectedFAD, "ConnectedFAD",
1610 "biasctrl and fadctrl are available and connected with their hardware.");
1611 AddStateName(Feedback::State::kConnected, "Connected",
1612 "biasctrl, fadctrl and fscctrl are available and connected with their hardware.");
1613
1614 AddStateName(Feedback::State::kFeedbackCtrlIdle, "FeedbackIdle",
1615 "Feedback control activated, but voltage output disabled.");
1616 AddStateName(Feedback::State::kTempCtrlIdle, "TempCtrlIdle",
1617 "Temperature control activated, but voltage output disabled.");
1618 AddStateName(Feedback::State::kCurrentCtrlIdle, "CurrentCtrlIdle",
1619 "Current control activated, but voltage output disabled.");
1620
1621 AddStateName(Feedback::State::kFeedbackCtrlRunning, "FeedbackControl",
1622 "Feedback control activated and voltage output enabled.");
1623 AddStateName(Feedback::State::kTempCtrlRunning, "TempControl",
1624 "Temperature control activated and voltage output enabled.");
1625 AddStateName(Feedback::State::kCurrentCtrlRunning, "CurrentControl",
1626 "Current/Temp control activated and voltage output enabled.");
1627 AddStateName(Feedback::State::kCalibrating, "Calibrating",
1628 "Calibrating current offsets.");
1629
1630 AddEvent("START_FEEDBACK_CONTROL", "S:1", Feedback::State::kConnectedFAD, Feedback::State::kConnected)
1631 (bind(&StateMachineFeedback::StartFeedback, this, placeholders::_1))
1632 ("Start the feedback control loop"
1633 "|Num[short]:Number of events 'medianed' to calculate the correction value");
1634
1635 AddEvent("START_GLOBAL_FEEDBACK", "S:1", Feedback::State::kConnectedFAD, Feedback::State::kConnected)
1636 (bind(&StateMachineFeedback::StartFeedbackGlobal, this, placeholders::_1))
1637 ("Start the global feedback control loop"
1638 "Num[short]:Number of events averaged to calculate the correction value");
1639
1640 AddEvent("START_TEMP_CONTROL", "F:1", Feedback::State::kConnectedFSC, Feedback::State::kConnected)
1641 (bind(&StateMachineFeedback::StartTempCtrl, this, placeholders::_1))
1642 ("Start the temperature control loop"
1643 "|offset[V]:Offset from the nominal temperature corrected value in Volts");
1644
1645 AddEvent("START_CURRENT_CONTROL", "F:1", Feedback::State::kConnectedFSC, Feedback::State::kConnected)
1646 (bind(&StateMachineFeedback::StartCurrentCtrl, this, placeholders::_1))
1647 ("Start the current/temperature control loop"
1648 "|offset[V]:Offset from the nominal current/temperature corrected value in Volts");
1649
1650 // Feedback::State::kTempCtrlIdle, Feedback::State::kFeedbackCtrlIdle, Feedback::State::kTempCtrlRunning, Feedback::State::kFeedbackCtrlRunning
1651 AddEvent("STOP")
1652 (bind(&StateMachineFeedback::StopFeedback, this))
1653 ("Stop any control loop");
1654
1655 AddEvent("ENABLE_OUTPUT", "B:1")//, Feedback::State::kIdle)
1656 (bind(&StateMachineFeedback::EnableOutput, this, placeholders::_1))
1657 ("Enable sending of correction values caluclated by the control loop to the biasctrl");
1658
1659 AddEvent("STORE_REFERENCE")//, Feedback::State::kIdle)
1660 (bind(&StateMachineFeedback::StoreReference, this))
1661 ("Store the last (averaged) value as new reference (for debug purpose only)");
1662
1663 AddEvent("SET_REFERENCE", "F:1")//, Feedback::State::kIdle)
1664 (bind(&StateMachineFeedback::SetReference, this, placeholders::_1))
1665 ("Set a new global reference value (for debug purpose only)");
1666
1667 AddEvent("SET_Ki", "D:1")//, Feedback::State::kIdle)
1668 (bind(&StateMachineFeedback::SetConstant, this, placeholders::_1, 0))
1669 ("Set integral constant Ki");
1670
1671 AddEvent("SET_Kp", "D:1")//, Feedback::State::kIdle)
1672 (bind(&StateMachineFeedback::SetConstant, this, placeholders::_1, 1))
1673 ("Set proportional constant Kp");
1674
1675 AddEvent("SET_Kd", "D:1")//, Feedback::State::kIdle)
1676 (bind(&StateMachineFeedback::SetConstant, this, placeholders::_1, 2))
1677 ("Set derivative constant Kd");
1678
1679 AddEvent("SET_T", "D:1")//, Feedback::State::kIdle)
1680 (bind(&StateMachineFeedback::SetConstant, this, placeholders::_1, 3))
1681 ("Set time-constant. (-1 to use the cycle time, i.e. the time for the last average cycle, instead)");
1682
1683 AddEvent("CALIBRATE_CURRENTS", Feedback::State::kConnectedFSC, Feedback::State::kConnected)//, Feedback::State::kIdle)
1684 (bind(&StateMachineFeedback::CalibrateCurrents, this))
1685 ("");
1686
1687 AddEvent("SET_CURRENT_REQUEST_INTERVAL", Feedback::State::kConnectedFSC, Feedback::State::kConnected)//, Feedback::State::kIdle)
1688 (bind(&StateMachineFeedback::SetCurrentRequestInterval, this, placeholders::_1))
1689 ("|interval[ms]:Interval between two current requests in modes which need that.");
1690
1691 // Verbosity commands
1692// AddEvent("SET_VERBOSE", "B:1")
1693// (bind(&StateMachineMCP::SetVerbosity, this, placeholders::_1))
1694// ("set verbosity state"
1695// "|verbosity[bool]:disable or enable verbosity for received data (yes/no), except dynamic data");
1696
1697 AddEvent("PRINT")
1698 (bind(&StateMachineFeedback::Print, this))
1699 ("");
1700
1701 AddEvent("PRINT_CALIBRATION")
1702 (bind(&StateMachineFeedback::PrintCalibration, this))
1703 ("");
1704 }
1705
1706 int EvalOptions(Configuration &conf)
1707 {
1708 if (!fMap.Read(conf.Get<string>("pixel-map-file")))
1709 {
1710 Error("Reading mapping table from "+conf.Get<string>("pixel-map-file")+" failed.");
1711 return 1;
1712 }
1713
1714 fGain = 0.1; // V(Amplitude) / V(Bias)
1715
1716 // 148 -> 248
1717
1718 // 33 : 10s < 2%
1719 // 50 : 5s < 2%
1720 // 66 : 3s < 2%
1721 // 85 : 2s < 2%
1722
1723 fKp = 0;
1724 fKd = 0;
1725 fKi = 0.75;
1726 fT = 1;
1727
1728 // Is that independent of the aboslute real amplitude of
1729 // the light pulser?
1730
1731 ostringstream msg;
1732 msg << "Control loop parameters: ";
1733 msg << "Kp=" << fKp << ", Kd=" << fKd << ", Ki=" << fKi << ", ";
1734 if (fT>0)
1735 msg << fT;
1736 else
1737 msg << "<auto>";
1738 msg << ", Gain(DRS/BIAS)=" << fGain << "V/V";
1739
1740 Message(msg);
1741
1742 fCurrentRequestInterval = conf.Get<uint16_t>("current-request-interval");
1743 fNumCalibIgnore = conf.Get<uint16_t>("num-calib-ignore");
1744 fNumCalibRequests = conf.Get<uint16_t>("num-calib-average");
1745 fCalibrationOffset = conf.Get<float>("calibration-offset");
1746
1747 return -1;
1748 }
1749};
1750
1751// ------------------------------------------------------------------------
1752
1753#include "Main.h"
1754
1755template<class T>
1756int RunShell(Configuration &conf)
1757{
1758 return Main::execute<T, StateMachineFeedback>(conf);
1759}
1760
1761void SetupConfiguration(Configuration &conf)
1762{
1763 po::options_description control("Feedback options");
1764 control.add_options()
1765 ("pixel-map-file", var<string>()->required(), "Pixel mapping file. Used here to get the default reference voltage.")
1766 ("current-request-interval", var<uint16_t>(1000), "Interval between two current requests.")
1767 ("num-calib-ignore", var<uint16_t>(30), "Number of current requests to be ignored before averaging")
1768 ("num-calib-average", var<uint16_t>(300), "Number of current requests to be averaged")
1769 ("calibration-offset", var<float>(-3), "Absolute offset relative to the G-APD operation voltage when calibrating")
1770 ;
1771
1772 conf.AddOptions(control);
1773}
1774
1775/*
1776 Extract usage clause(s) [if any] for SYNOPSIS.
1777 Translators: "Usage" and "or" here are patterns (regular expressions) which
1778 are used to match the usage synopsis in program output. An example from cp
1779 (GNU coreutils) which contains both strings:
1780 Usage: cp [OPTION]... [-T] SOURCE DEST
1781 or: cp [OPTION]... SOURCE... DIRECTORY
1782 or: cp [OPTION]... -t DIRECTORY SOURCE...
1783 */
1784void PrintUsage()
1785{
1786 cout <<
1787 "The feedback control the BIAS voltages based on the calibration signal.\n"
1788 "\n"
1789 "The default is that the program is started without user intercation. "
1790 "All actions are supposed to arrive as DimCommands. Using the -c "
1791 "option, a local shell can be initialized. With h or help a short "
1792 "help message about the usuage can be brought to the screen.\n"
1793 "\n"
1794 "Usage: feedback [-c type] [OPTIONS]\n"
1795 " or: feedback [OPTIONS]\n";
1796 cout << endl;
1797}
1798
1799void PrintHelp()
1800{
1801 Main::PrintHelp<StateMachineFeedback>();
1802
1803 /* Additional help text which is printed after the configuration
1804 options goes here */
1805
1806 /*
1807 cout << "bla bla bla" << endl << endl;
1808 cout << endl;
1809 cout << "Environment:" << endl;
1810 cout << "environment" << endl;
1811 cout << endl;
1812 cout << "Examples:" << endl;
1813 cout << "test exam" << endl;
1814 cout << endl;
1815 cout << "Files:" << endl;
1816 cout << "files" << endl;
1817 cout << endl;
1818 */
1819}
1820
1821int main(int argc, const char* argv[])
1822{
1823 Configuration conf(argv[0]);
1824 conf.SetPrintUsage(PrintUsage);
1825 Main::SetupConfiguration(conf);
1826 SetupConfiguration(conf);
1827
1828 if (!conf.DoParse(argc, argv, PrintHelp))
1829 return 127;
1830
1831 //try
1832 {
1833 // No console access at all
1834 if (!conf.Has("console"))
1835 {
1836// if (conf.Get<bool>("no-dim"))
1837// return RunShell<LocalStream, StateMachine, ConnectionFSC>(conf);
1838// else
1839 return RunShell<LocalStream>(conf);
1840 }
1841 // Cosole access w/ and w/o Dim
1842/* if (conf.Get<bool>("no-dim"))
1843 {
1844 if (conf.Get<int>("console")==0)
1845 return RunShell<LocalShell, StateMachine, ConnectionFSC>(conf);
1846 else
1847 return RunShell<LocalConsole, StateMachine, ConnectionFSC>(conf);
1848 }
1849 else
1850*/ {
1851 if (conf.Get<int>("console")==0)
1852 return RunShell<LocalShell>(conf);
1853 else
1854 return RunShell<LocalConsole>(conf);
1855 }
1856 }
1857 /*catch (std::exception& e)
1858 {
1859 cerr << "Exception: " << e.what() << endl;
1860 return -1;
1861 }*/
1862
1863 return 0;
1864}
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