/[PAMELA software]/PamelaDigitizer/DigitizeCalo.cxx
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Annotation of /PamelaDigitizer/DigitizeCalo.cxx

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Revision 1.4 - (hide annotations) (download)
Fri Nov 13 09:08:53 2009 UTC (15 years ago) by pizzolot
Branch: MAIN
Changes since 1.3: +3 -1 lines
fixed crc calculation of TOF and CALOCompress, implemented crc of AC

1 pamelats 1.1 #include "Digitizer.h"
2    
3     extern "C"{
4     short crc(short, short);
5     };
6    
7     void Digitizer::ClearCaloCalib(Int_t s){
8     //
9     fcstwerr[s] = 0;
10     fcperror[s] = 0.;
11     for ( Int_t d=0 ; d<11 ;d++ ){
12     Int_t pre = -1;
13     for ( Int_t j=0; j<96 ;j++){
14     if ( j%16 == 0 ) pre++;
15     fcalped[s][d][j] = 0.;
16     fcstwerr[s] = 0.;
17     fcperror[s] = 0.;
18     fcalgood[s][d][j] = 0.;
19     fcalthr[s][d][pre] = 0.;
20     fcalrms[s][d][j] = 0.;
21     fcalbase[s][d][pre] = 0.;
22     fcalvar[s][d][pre] = 0.;
23     };
24     };
25     return;
26     }
27    
28     Int_t Digitizer::CaloLoadCalib(Int_t s,TString fcalname, UInt_t calibno){
29     //
30     //
31     UInt_t e = 0;
32     if ( s == 0 ) e = 0;
33     if ( s == 1 ) e = 2;
34     if ( s == 2 ) e = 3;
35     if ( s == 3 ) e = 1;
36     //
37     ifstream myfile;
38     myfile.open(fcalname.Data());
39     if ( !myfile ){
40     return(-107);
41     };
42     myfile.close();
43     //
44     TFile *File = new TFile(fcalname.Data());
45     if ( !File ) return(-108);
46     TTree *tr = (TTree*)File->Get("CalibCalPed");
47     if ( !tr ) return(-109);
48     //
49     TBranch *calo = tr->GetBranch("CalibCalPed");
50     //
51     pamela::CalibCalPedEvent *ce = 0;
52     tr->SetBranchAddress("CalibCalPed", &ce);
53     //
54     Long64_t ncalibs = calo->GetEntries();
55     //
56     if ( !ncalibs ) return(-110);
57     //
58     calo->GetEntry(calibno);
59     //
60     if (ce->cstwerr[s] != 0 && ce->cperror[s] == 0 ) {
61     fcstwerr[s] = ce->cstwerr[s];
62     fcperror[s] = ce->cperror[s];
63     for ( Int_t d=0 ; d<11 ;d++ ){
64     Int_t pre = -1;
65     for ( Int_t j=0; j<96 ;j++){
66     if ( j%16 == 0 ) pre++;
67     fcalped[s][d][j] = ce->calped[e][d][j];
68     fcalgood[s][d][j] = ce->calgood[e][d][j];
69     fcalthr[s][d][pre] = ce->calthr[e][d][pre];
70     fcalrms[s][d][j] = ce->calrms[e][d][j];
71     fcalbase[s][d][pre] = ce->calbase[e][d][pre];
72     fcalvar[s][d][pre] = ce->calvar[e][d][pre];
73     };
74     };
75     } else {
76     printf(" CALORIMETER - ERROR: problems finding a good calibration in this file! \n\n ");
77     File->Close();
78     return(-111);
79     };
80     File->Close();
81     return(0);
82     }
83    
84    
85     void Digitizer::DigitizeCALOCALIB() {
86     //
87     // Header of the four sections
88     //
89     fSecCalo[0] = 0xAA00; // XE
90     fSecCalo[1] = 0xB100; // XO
91     fSecCalo[2] = 0xB600; // YE
92     fSecCalo[3] = 0xAD00; // YO
93     //
94     // length of the data is 0x1215
95     //
96     fSecCALOLength[0] = 0x1215; // XE
97     fSecCALOLength[1] = 0x1215; // XO
98     fSecCALOLength[2] = 0x1215; // YE
99     fSecCALOLength[3] = 0x1215; // YO
100     //
101     Int_t chksum = 0;
102     UInt_t tstrip = 0;
103     UInt_t fSecPointer = 0;
104     //
105     for (Int_t sec=0; sec < 4; sec++){
106     //
107     // sec = 0 -> XE 1 -> XO 2-> YE 3 -> YO
108     //
109     fCALOlength = 0;
110     memset(fDataCALO,0,sizeof(UShort_t)*fCALObuffer);
111     fSecPointer = fCALOlength;
112     //
113     // First of all we have section header and packet length
114     //
115     fDataCALO[fCALOlength] = fSecCalo[sec];
116     fCALOlength++;
117     fDataCALO[fCALOlength] = fSecCALOLength[sec];
118     fCALOlength++;
119     //
120     // Section XO is read in the opposite direction respect to the others
121     //
122     chksum = 0;
123     //
124     for (Int_t plane=0; plane < 11; plane++){
125     //
126     if ( sec == 1 ) tstrip = fCALOlength + 96*2;
127     //
128     for (Int_t strip=0; strip < 96; strip++){
129     //
130     chksum += (Int_t)fcalped[sec][plane][strip];
131     //
132     // save value
133     //
134     if ( sec == 1 ){
135     tstrip -= 2;
136     fDataCALO[tstrip] = (Int_t)fcalped[sec][plane][strip];
137     fDataCALO[tstrip+1] = (Int_t)fcalgood[sec][plane][strip];
138     } else {
139     fDataCALO[fCALOlength] = (Int_t)fcalped[sec][plane][strip];
140     fDataCALO[fCALOlength+1] = (Int_t)fcalgood[sec][plane][strip];
141     };
142     fCALOlength +=2;
143     };
144     //
145     };
146     //
147     fDataCALO[fCALOlength] = (UShort_t)chksum;
148     fCALOlength++;
149     fDataCALO[fCALOlength] = 0;
150     fCALOlength++;
151     fDataCALO[fCALOlength] = (UShort_t)((Int_t)(chksum >> 16));
152     fCALOlength++;
153     //
154     // Section XO is read in the opposite direction respect to the others
155     //
156     chksum = 0;
157     //
158     for (Int_t plane=0; plane < 11; plane++){
159     //
160     if ( sec == 1 ) tstrip = fCALOlength+6*2;
161     //
162     for (Int_t strip=0; strip < 6; strip++){
163     //
164     chksum += (Int_t)fcalthr[sec][plane][strip];
165     //
166     // save value
167     //
168     if ( sec == 1 ){
169     tstrip -= 2;
170     fDataCALO[tstrip] = 0;
171     fDataCALO[tstrip+1] = (Int_t)fcalthr[sec][plane][strip];
172     } else {
173     fDataCALO[fCALOlength] = 0;
174     fDataCALO[fCALOlength+1] = (Int_t)fcalthr[sec][plane][strip];
175     };
176     fCALOlength +=2;
177     };
178     //
179     };
180     //
181     fDataCALO[fCALOlength] = 0;
182     fCALOlength++;
183     fDataCALO[fCALOlength] = (UShort_t)chksum;
184     fCALOlength++;
185     fDataCALO[fCALOlength] = 0;
186     fCALOlength++;
187     fDataCALO[fCALOlength] = (UShort_t)((Int_t)(chksum >> 16));
188     fCALOlength++;
189     //
190     // Section XO is read in the opposite direction respect to the others
191     //
192     for (Int_t plane=0; plane < 11; plane++){
193     //
194     if ( sec == 1 ) tstrip = fCALOlength+96*2;
195     //
196     for (Int_t strip=0; strip < 96; strip++){
197     //
198     // save value
199     //
200     if ( sec == 1 ){
201     tstrip -= 2;
202     fDataCALO[tstrip] = 0;
203     fDataCALO[tstrip+1] = (Int_t)fcalrms[sec][plane][strip];
204     } else {
205     fDataCALO[fCALOlength] = 0;
206     fDataCALO[fCALOlength+1] = (Int_t)fcalrms[sec][plane][strip];
207     };
208     fCALOlength += 2;
209     };
210     //
211     };
212     //
213     // Section XO is read in the opposite direction respect to the others
214     //
215     for (Int_t plane=0; plane < 11; plane++){
216     //
217     if ( sec == 1 ) tstrip = fCALOlength+6*4;
218     //
219     for (Int_t strip=0; strip < 6; strip++){
220     //
221     // save value
222     //
223     if ( sec == 1 ){
224     tstrip -= 4;
225     fDataCALO[tstrip] = 0;
226     fDataCALO[tstrip+1] = (Int_t)fcalbase[sec][plane][strip];
227     fDataCALO[tstrip+2] = 0;
228     fDataCALO[tstrip+3] = (Int_t)fcalvar[sec][plane][strip];
229     } else {
230     fDataCALO[fCALOlength] = 0;
231     fDataCALO[fCALOlength+1] = (Int_t)fcalbase[sec][plane][strip];
232     fDataCALO[fCALOlength+2] = 0;
233     fDataCALO[fCALOlength+3] = (Int_t)fcalvar[sec][plane][strip];
234     };
235     fCALOlength +=4;
236     };
237     //
238     };
239     //
240     //
241     // here we calculate and save the CRC
242     //
243     fDataCALO[fCALOlength] = 0;
244     fCALOlength++;
245     Short_t CRC = 0;
246     for (UInt_t i=0; i<(fCALOlength-fSecPointer); i++){
247     CRC=crc(CRC,fDataCALO[i+fSecPointer]);
248     };
249     fDataCALO[fCALOlength] = (UShort_t)CRC;
250     fCALOlength++;
251     //
252     UInt_t length=fCALOlength*2;
253     DigitizePSCU(length,0x18,fDataPSCU);
254     //
255     // Add padding to 64 bits
256     //
257     AddPadding();
258     //
259     fOutputfile.write(reinterpret_cast<char*>(fDataPSCU),sizeof(UShort_t)*fPSCUbuffer);
260     UShort_t temp[1000000];
261     memset(temp,0,sizeof(UShort_t)*1000000);
262     swab(fDataCALO,temp,sizeof(UShort_t)*fCALOlength); // WE MUST SWAP THE BYTES!!!
263     fOutputfile.write(reinterpret_cast<char*>(temp),sizeof(UShort_t)*fCALOlength);
264     //
265     // padding to 64 bytes
266     //
267     if ( fPadding ){
268     fOutputfile.write(reinterpret_cast<char*>(fDataPadding),sizeof(UChar_t)*fPadding);
269     };
270     //
271     //
272     };
273     //
274     };
275    
276     void Digitizer::CaloLoadCalib() {
277     //
278     fGivenCaloCalib = 0; // ####@@@@ should be given as input par @@@@####
279     //
280     // first of all load the MIP to ADC conversion values
281     //
282     stringstream calfile;
283     Int_t error = 0;
284     GL_PARAM *glparam = new GL_PARAM();
285     //
286     // determine where I can find calorimeter ADC to MIP conversion file
287     //
288     error = 0;
289     error = glparam->Query_GL_PARAM(3,101,fDbc);
290     //
291     calfile.str("");
292     calfile << glparam->PATH.Data() << "/";
293     calfile << glparam->NAME.Data();
294     //
295     printf("\n Using Calorimeter ADC to MIP conversion file: \n %s \n",calfile.str().c_str());
296     FILE *f;
297     f = fopen(calfile.str().c_str(),"rb");
298     //
299     memset(fCalomip,0,4224*sizeof(fCalomip[0][0][0]));
300     //
301     for (Int_t m = 0; m < 2 ; m++ ){
302     for (Int_t k = 0; k < 22; k++ ){
303     for (Int_t l = 0; l < 96; l++ ){
304     fread(&fCalomip[m][k][l],sizeof(fCalomip[m][k][l]),1,f);
305     };
306     };
307     };
308     fclose(f);
309     //
310     // determine which calibration has to be used and load it for each section
311     //
312     GL_CALO_CALIB *glcalo = new GL_CALO_CALIB();
313     GL_ROOT *glroot = new GL_ROOT();
314     TString fcalname;
315     UInt_t idcalib;
316     UInt_t calibno;
317     UInt_t utime = 0;
318     //
319     for (UInt_t s=0; s<4; s++){
320     //
321     // clear calo calib variables for section s
322     //
323     ClearCaloCalib(s);
324     //
325     if ( fGivenCaloCalib ){
326     //
327     // a time has been given as input on the command line so retrieve the calibration that preceed that time
328     //
329     glcalo->Query_GL_CALO_CALIB(fGivenCaloCalib,utime,s,fDbc);
330     //
331     calibno = glcalo->EV_ROOT;
332     idcalib = glcalo->ID_ROOT_L0;
333     //
334     // determine path and name and entry of the calibration file
335     //
336     printf("\n");
337     printf(" ** SECTION %i **\n",s);
338     //
339     glroot->Query_GL_ROOT(idcalib,fDbc);
340     //
341     stringstream name;
342     name.str("");
343     name << glroot->PATH.Data() << "/";
344     name << glroot->NAME.Data();
345     //
346     fcalname = (TString)name.str().c_str();
347     //
348     printf("\n Section %i : using file %s calibration at entry %i: \n",s,fcalname.Data(),calibno);
349     //
350     } else {
351     error = 0;
352     error = glparam->Query_GL_PARAM(1,104,fDbc);
353     //
354     calfile.str("");
355     calfile << glparam->PATH.Data() << "/";
356     calfile << glparam->NAME.Data();
357     //
358     printf("\n Section %i : using default calorimeter calibration: \n %s \n",s,calfile.str().c_str());
359     //
360     fcalname = (TString)calfile.str().c_str();
361     calibno = s;
362     //
363     };
364     //
365     // load calibration variables in memory
366     //
367     CaloLoadCalib(s,fcalname,calibno);
368     //
369     };
370     //
371     // at this point we have in memory the calorimeter calibration and we can save it to disk in the correct format and use it to digitize the data
372     //
373     delete glparam;
374     delete glcalo;
375     delete glroot;
376     };
377    
378     void Digitizer::DigitizeCALO() {
379     //
380     //
381     fCALOlength = 0; // reset total dimension of calo data
382     //
383     // gpamela variables to be used
384     //
385     // fhBookTree->SetBranchStatus("Nthcali",1);//modified by E.Vannuccini 03/08
386     // fhBookTree->SetBranchStatus("Icaplane",1);
387     // fhBookTree->SetBranchStatus("Icastrip",1);
388     // fhBookTree->SetBranchStatus("Icamod",1);
389     // fhBookTree->SetBranchStatus("Enestrip",1);
390     //
391     // call different routines depending on the acq mode you want to simulate
392     //
393     switch ( fModCalo ){
394     case 0:
395     this->DigitizeCALORAW();
396     break;
397     case 1:
398     this->DigitizeCALOCOMPRESS();
399     break;
400     case 2:
401     this->DigitizeCALOFULL();
402     break;
403     };
404     //
405     };
406    
407     Float_t Digitizer::GetCALOen(Int_t sec, Int_t plane, Int_t strip){
408     //
409     // determine plane and strip
410     //
411     Int_t mplane = 0;
412     //
413     // wrong!
414     //
415     // if ( sec == 0 || sec == 3 ) mplane = (plane * 4) + sec + 1;
416     // if ( sec == 1 ) mplane = (plane * 4) + 2 + 1;
417     // if ( sec == 2 ) mplane = (plane * 4) + 1 + 1;
418     //
419     if ( sec == 0 ) mplane = plane * 4 + 1; // it must be 0, 4, 8, ... (+1) from plane = 0, 11
420     if ( sec == 1 ) mplane = plane * 4 + 2 + 1; // it must be 2, 6, 10, ... (+1) from plane = 0, 11
421     if ( sec == 2 ) mplane = plane * 4 + 3 + 1; // it must be 3, 7, 11, ... (+1) from plane = 0, 11
422     if ( sec == 3 ) mplane = plane * 4 + 1 + 1; // it must be 1, 5, 9, ... (+1) from plane = 0, 11
423     //
424     Int_t mstrip = strip + 1;
425     //
426     // search energy release in gpamela output
427     //
428     for (Int_t i=0; i<Nthcali;i++){
429     if ( Icaplane[i] == mplane && Icastrip[i] == mstrip ){
430     return (Enestrip[i]);
431     };
432     };
433     //
434     // if not found it means no energy release so return 0.
435     //
436     return(0.);
437     };
438    
439     void Digitizer::DigitizeCALORAW() {
440     //
441     // some variables
442     //
443     Float_t ens = 0.;
444     UInt_t adcsig = 0;
445     UInt_t adcbase = 0;
446     UInt_t adc = 0;
447     Int_t pre = 0;
448     UInt_t l = 0;
449     UInt_t lpl = 0;
450     UInt_t tstrip = 0;
451     UInt_t fSecPointer = 0;
452     Double_t pedenoise;
453     Float_t rms = 0.;
454     Float_t pedestal = 0.;
455     //
456     // clean the data structure
457     //
458     memset(fDataCALO,0,sizeof(UShort_t)*fCALObuffer);
459     //
460     // Header of the four sections
461     //
462     fSecCalo[0] = 0xEA08; // XE
463     fSecCalo[1] = 0xF108; // XO
464     fSecCalo[2] = 0xF608; // YE
465     fSecCalo[3] = 0xED08; // YO
466     //
467     // length of the data is 0x0428 in RAW mode
468     //
469     fSecCALOLength[0] = 0x0428; // XE
470     fSecCALOLength[1] = 0x0428; // XO
471     fSecCALOLength[2] = 0x0428; // YE
472     fSecCALOLength[3] = 0x0428; // YO
473     //
474     // let's start
475     //
476     fCALOlength = 0;
477     //
478     for (Int_t sec=0; sec < 4; sec++){
479     //
480     // sec = 0 -> XE 1 -> XO 2-> YE 3 -> YO
481     //
482     l = 0; // XE and XO are Y planes
483     if ( sec < 2 ) l = 1; // while YE and YO are X planes
484     //
485     fSecPointer = fCALOlength;
486     //
487     // First of all we have section header and packet length
488     //
489     fDataCALO[fCALOlength] = fSecCalo[sec];
490     fCALOlength++;
491     fDataCALO[fCALOlength] = fSecCALOLength[sec];
492     fCALOlength++;
493     //
494     // selftrigger coincidences - in the future we should add here some code to simulate timing response of pre-amplifiers
495     //
496     for (Int_t autoplane=0; autoplane < 7; autoplane++){
497     fDataCALO[fCALOlength] = 0x0000;
498     fCALOlength++;
499     };
500     //
501     //
502     // here comes data
503     //
504     //
505     // Section XO is read in the opposite direction respect to the others
506     //
507     if ( sec == 1 ){
508     tstrip = 96*11 + fCALOlength;
509     } else {
510     tstrip = 0;
511     };
512     //
513     pre = -1;
514     //
515     for (Int_t strip=0; strip < 96; strip++){
516     //
517     // which is the pre for this strip?
518     //
519     if (strip%16 == 0) {
520     pre++;
521     };
522     //
523     if ( sec == 1 ) tstrip -= 11;
524     //
525     for (Int_t plane=0; plane < 11; plane++){
526     //
527     // here is wrong!!!!
528     //
529     //
530     // if ( plane%2 == 0 && sec%2 != 0){
531     // lpl = plane*2;
532     // } else {
533     // lpl = (plane*2) + 1;
534     // };
535     //
536     if ( sec == 0 || sec == 3 ) lpl = plane * 2;
537     if ( sec == 1 || sec == 2 ) lpl = (plane * 2) + 1;
538     //
539     // get the energy in GeV from the simulation for that strip
540     //
541     ens = this->GetCALOen(sec,plane,strip);
542     //
543     // convert it into ADC channels
544     //
545     adcsig = int(ens*fCalomip[l][lpl][strip]/fCALOGeV2MIPratio);
546     //
547     // sum baselines
548     //
549     adcbase = (UInt_t)fcalbase[sec][plane][pre];
550     //
551     // add noise and pedestals
552     //
553     pedestal = fcalped[sec][plane][strip];
554     rms = fcalrms[sec][plane][strip]/4.;
555     //
556     // Add random gaussian noise of RMS rms and Centered in the pedestal
557     //
558     pedenoise = gRandom->Gaus((Double_t)pedestal,(Double_t)rms);
559     //
560     // Sum all contribution
561     //
562     adc = adcsig + adcbase + (Int_t)round(pedenoise);
563     //
564     // Signal saturation
565     //
566     if ( adc > 0x7FFF ) adc = 0x7FFF;
567     //
568     // save value
569     //
570     if ( sec == 1 ){
571     fDataCALO[tstrip] = adc;
572     tstrip++;
573     } else {
574     fDataCALO[fCALOlength] = adc;
575     };
576     fCALOlength++;
577     //
578     };
579     //
580     if ( sec == 1 ) tstrip -= 11;
581     //
582     };
583     //
584     // here we calculate and save the CRC
585     //
586     Short_t CRC = 0;
587     for (UInt_t i=0; i<(fCALOlength-fSecPointer); i++){
588     CRC=crc(CRC,fDataCALO[i+fSecPointer]);
589     };
590     fDataCALO[fCALOlength] = (UShort_t)CRC;
591     fCALOlength++;
592     //
593     };
594     //
595     // for (Int_t i=0; i<fCALOlength; i++){
596     // printf(" WORD %i DIGIT %0x \n",i,fDataCALO[i]);
597     // };
598     //
599     };
600    
601 pizzolot 1.3
602 pamelats 1.1 void Digitizer::DigitizeCALOCOMPRESS() {
603     //
604 pizzolot 1.3 // CompressMode: implemented by C.Pizzolotto october 2009
605     //
606     // some variables
607 pamelats 1.1 //
608 pizzolot 1.3 Float_t ens = 0.;
609     UInt_t adcsig = 0;
610     UInt_t adcbase = 0;
611     UInt_t adc[16];
612     Float_t rms = 0.;
613     Double_t pedenoise=0.;
614     Float_t pedestal = 0.;
615     UInt_t pedround[16];
616     Float_t thres[16];
617     Float_t goodflag[16];
618     UInt_t min_adc = 0x7FFF;
619     UInt_t min_adc_ch = 0;
620     UInt_t l = 0;
621     UInt_t lpl = 0;
622     Int_t plane = 0;
623     Int_t pre;
624     Int_t npre = 0; // number of pre between 0-5
625     UInt_t strip = 0;
626     UInt_t remainder;
627     Float_t basesum=0.;
628     Float_t basenof=0.;
629     UInt_t baseline=0;
630     UInt_t fSecPointer = 0;
631     UInt_t fNofTStripsPointer = 0;
632     UInt_t NofTransmittedStrips = 0 ;
633 pamelats 1.1 //
634 pizzolot 1.3 // clean the data structure
635 pamelats 1.1 //
636 pizzolot 1.3 memset(adc, 0,sizeof(adc));
637     memset(pedround, 0,sizeof(pedround));
638     memset(thres, 0,sizeof(thres));
639     memset(goodflag, 0,sizeof(goodflag));
640 pamelats 1.1 //
641 pizzolot 1.3 memset(fDataCALO,0,sizeof(UShort_t)*fCALObuffer);
642 pamelats 1.1 //
643 pizzolot 1.3 // Header of the four sections
644 pamelats 1.1 //
645 pizzolot 1.3 fSecCalo[0] = 0xEA00; // XE
646     fSecCalo[1] = 0xF100; // XO
647     fSecCalo[2] = 0xF600; // YE
648     fSecCalo[3] = 0xED00; // YO
649 pamelats 1.1 //
650     // here comes raw data
651     //
652 pizzolot 1.3 fCALOlength = 0;
653 pamelats 1.1 //
654 pizzolot 1.3 for (Int_t sec=0; sec < 4; sec++){ //
655     //
656     // sec = 0 -> XE 1 -> XO 2-> YE 3 -> YO
657     //
658     l = 0; // XE and XO are Y planes
659     if ( sec < 2 ) l = 1; // while YE and YO are X planes
660     //
661     fSecPointer = fCALOlength;
662     //
663     // First of all we have section header and packet length
664     //
665     fDataCALO[fCALOlength] = fSecCalo[sec];
666     fCALOlength++;
667     fDataCALO[fCALOlength] = 0; // Unknown: length must be calculated on fly
668     fCALOlength++;
669     //
670     // selftrigger coincidences - in the future we should add here some code to simulate timing response of pre-amplifiers
671     //
672     for (Int_t autoplane=0; autoplane < 7; autoplane++){
673     fDataCALO[fCALOlength] = 0x0000;
674     fCALOlength++;
675     };
676     //
677     // second level trigger
678     //
679     fDataCALO[fCALOlength] = 0x0000;
680     fCALOlength++;
681     //
682     // Nof strips transmetted: must be calculated on fly
683     //
684     fNofTStripsPointer = fCALOlength;
685     fDataCALO[fCALOlength] = 0x0000;
686     fCALOlength++;
687     NofTransmittedStrips=0;
688     //
689     // Identifier of calo data
690     //
691     fDataCALO[fCALOlength] = 0xCA50;
692     fCALOlength++;
693     fDataCALO[fCALOlength] = 0xCA50;
694     fCALOlength++;
695     fDataCALO[fCALOlength] = 0xFFFF; // compress mode
696     fCALOlength++;
697     //
698     // Pedestal threashold table checksum
699     //
700     fDataCALO[fCALOlength] = 0x0000;
701     fCALOlength++;
702     //
703     // Calorimeter event counter
704     //
705     fDataCALO[fCALOlength] = fEvent;
706     fCALOlength++;
707     //
708     // Start here with data
709     //
710     plane=-1;
711     npre =-1;
712     for (Int_t ipre=0; ipre< 66; ipre++){ // (11 planes*6 preampl)
713     //
714     // which plane
715     if ( (ipre % 6) == 0) {
716     plane++;
717     }
718     //
719     pre=ipre;
720     //
721     // Adjust counter for plane X0
722     if (sec==1) // conto invertito
723     {
724     remainder = pre % 6 ;
725     pre = ((plane+1)*6) - remainder ;
726     }
727     //
728     if ( sec == 0 || sec == 3 ) lpl = plane * 2;
729     if ( sec == 1 || sec == 2 ) lpl = (plane * 2) + 1;
730     //
731     // initialize min_adc
732     min_adc = 0x7FFF;
733     for (Int_t ch=0; ch <16; ch++){ // 16 channels each pre
734     //
735     // strip number
736     //
737     strip=((pre-(6*plane))*16)+ch;
738     if(sec==1) strip = ((pre-(6*plane))*16)+(15-ch)-16;
739     //
740     // calculate npre: a number between 0-5
741     //
742     if( sec==1) {
743     if ( ((95-strip) % 16) == 0) {
744     npre++;
745     if(npre>5) npre=0;
746     }
747     } else {
748     if ( (strip % 16) == 0) {
749     npre++;
750     if(npre>5) npre=0;
751     }
752     }
753     //
754     // get the energy in GeV from the simulation for that strip
755     //
756     ens = this->GetCALOen(sec,plane,strip);
757     //
758     // convert it into ADC channels
759     //
760     adcsig = int(ens*fCalomip[l][lpl][strip]/fCALOGeV2MIPratio);
761     //
762     // sum baselines
763     //
764     adcbase = (UInt_t)fcalbase[sec][plane][npre];
765     //
766     // add noise and pedestals
767     //
768     pedestal = fcalped[sec][plane][strip];
769     rms = fcalrms[sec][plane][strip]/4.;
770     //
771     // Add random gaussian noise of RMS rms and Centered in the pedestal
772     //
773     pedenoise = gRandom->Gaus((Double_t)pedestal,(Double_t)rms);
774     //
775     // Sum all contribution
776     //
777     adc[ch] = adcsig + adcbase + (Int_t)round(pedenoise);
778     //
779     // Signal saturation
780     //
781     if ( adc[ch] > 0x7FFF ) adc[ch] = 0x7FFF;
782     //
783     // save infos
784     //
785     pedround[ch] = (Int_t)round(pedestal) ;
786     thres[ch] = ( fcalthr[sec][plane][npre] );
787     goodflag[ch] = ( fcalgood[sec][plane][strip] ); // if bad should be 255
788     //
789     // Find minimum adc in this preamp
790     //
791     if ( goodflag[ch]==0 && (adc[ch]-pedround[ch])<min_adc )
792     {
793     min_adc = ( adc[ch]-pedround[ch] ) ;
794     min_adc_ch = ch ;
795     };
796     }; // close channel loop ch
797     //
798     // Find how many channels are below threshold in current preampl
799     //
800     Int_t nof_chs_below = 0;
801     for (Int_t ch=0; ch <16; ch++){
802     if ( goodflag[ch]==0 && ((adc[ch]-pedround[ch]) < (min_adc+thres[min_adc_ch])) )
803     nof_chs_below++;
804 pamelats 1.1 };
805 pizzolot 1.3 //
806     // Transmit data: CASE nof_chs_below<9
807     //
808     if(nof_chs_below<9)
809     {
810     if(sec==1) {
811     fDataCALO[fCALOlength] = 0x1000 + ipre ;
812     } else {
813     fDataCALO[fCALOlength] = 0x1000 + pre ;
814     };
815     fCALOlength++;
816     for (Int_t ch=0; ch <16; ch++)
817     {
818     fDataCALO[fCALOlength] = adc[ch];
819     fCALOlength++;
820     NofTransmittedStrips++;
821     };
822     }
823     else
824     //
825     // Transmit data: CASE nof_chs_below>=9
826     //
827     {
828     if(sec==1) {
829     fDataCALO[fCALOlength] = 0x0800 + ipre ;
830     } else {
831     fDataCALO[fCALOlength] = 0x0800 + pre;
832     };
833     fCALOlength++;
834     //
835     // calculate baseline and save it
836     //
837     basenof=0;
838     baseline=0;
839     basesum=0;
840     for (Int_t ch=0; ch <16; ch++){
841     if( goodflag[ch]==0 && ( (adc[ch]-pedround[ch])<(min_adc+thres[ch]) ) )
842     {
843     basesum = basesum + (adc[ch]-pedround[ch]) ;
844     basenof++;
845     };
846     };
847     baseline = (Int_t)round( basesum / basenof );
848     fDataCALO[fCALOlength] = baseline;
849     fCALOlength++;
850     //
851     // Transmit only channels > (min_adc+thres[ch])
852     //
853     for (Int_t ch=0; ch <16; ch++){
854     if ( (adc[ch]-pedround[ch] )>(min_adc+thres[ch]) )
855     {
856     fDataCALO[fCALOlength] = ch;
857     fCALOlength++;
858     fDataCALO[fCALOlength] = adc[ch];
859     fCALOlength++;
860     NofTransmittedStrips++;
861     };
862     };
863     }; // close if nof_chs_below
864     }; // close preampl loop
865     //
866     // Write the correct length
867     //
868 pizzolot 1.4 fDataCALO[fSecPointer+1] = (fCALOlength-fSecPointer+1)-2 ;
869     // total length of the packet: -2: because the words with status and length are not included
870 pizzolot 1.3 fDataCALO[fNofTStripsPointer] = NofTransmittedStrips ;
871     //
872     // here we calculate and save the CRC
873     //
874     Short_t CRC = 0;
875 pizzolot 1.4 fDataCALO[fCALOlength] =0 ;
876 pizzolot 1.3 for (UInt_t i=0; i<(fCALOlength-fSecPointer); i++){
877     CRC=crc(CRC,fDataCALO[i+fSecPointer]);
878 pamelats 1.1 };
879 pizzolot 1.3 fDataCALO[fCALOlength] = (UShort_t)CRC;
880     fCALOlength++;
881     //
882     }; // close sec loop
883     // The End
884     }
885    
886 pamelats 1.1
887 pizzolot 1.3
888 pamelats 1.1 void Digitizer::DigitizeCALOFULL() {
889     //
890 pizzolot 1.3 printf(" FULL MODE STILL NOT IMPLEMENTED! %d\n",fEvent);
891 pamelats 1.1 //
892     this->DigitizeCALORAW();
893     return;
894     //
895     fSecCalo[0] = 0xEA00;
896     fSecCalo[1] = 0xF100;
897     fSecCalo[2] = 0xF600;
898     fSecCalo[3] = 0xED00;
899     //
900     // length of the data in DSP mode must be calculated on fly during digitization
901     //
902     memset(fSecCALOLength,0x0,4*sizeof(UShort_t));
903     //
904     // here comes raw data
905     //
906     Int_t en = 0;
907     //
908     for (Int_t sec=0; sec < 4; sec++){
909     fDataCALO[en] = fSecCalo[sec];
910     en++;
911     fDataCALO[en] = fSecCALOLength[sec];
912     en++;
913     for (Int_t plane=0; plane < 11; plane++){
914     for (Int_t strip=0; strip < 11; strip++){
915     fDataCALO[en] = 0x0;
916     en++;
917     };
918     };
919     };
920     //
921 pizzolot 1.3 }

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