/[PAMELA software]/calo/flight/CaloFranzini/src/Calib.cpp
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Contents of /calo/flight/CaloFranzini/src/Calib.cpp

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Revision 1.4 - (show annotations) (download)
Fri Jan 11 15:27:13 2008 UTC (16 years, 11 months ago) by mocchiut
Branch: MAIN
Changes since 1.3: +269 -72 lines
changes

1 #include <stdlib.h>
2 #include <iostream>
3 #include <iomanip>
4 //
5 #include <TString.h>
6 #include <TH1F.h>
7 #include <TH2F.h>
8 #include <TMatrixD.h>
9 #include <TMatrixF.h>
10 #include <TArrayF.h>
11 #include <TArrayI.h>
12 //
13 #include <PamLevel2.h>
14 #include <CaloFranzini.h>
15 //
16 using namespace std;
17 //
18 extern Bool_t MATRIX;
19 extern Bool_t FULL;
20 extern Bool_t SIMU;
21 extern Bool_t CRIG;
22 extern Bool_t SRIG;
23 CaloFranzini *cf;
24 Int_t nbin;
25 Float_t rig[18];
26 Float_t rmean[17];
27 Int_t ntot[17];
28 Int_t MDIM = 8213;
29 //Int_t MDIM = 4128;
30 //Float_t qqplane[17][43];
31 //Int_t nnqplane[17][43];
32
33 TArrayF *qplane[17];
34 TArrayI *nqplane[17];
35 TMatrixD *matrix[17];
36 TMatrixD *nmat[17];
37
38 TMatrixD *fqplane;
39 TMatrixD *fnqplane;
40 //TMatrixD *fqplane[17];
41 //TMatrixD *fnqplane[17];
42 //TMatrixF *fmatrix[17];
43 //TMatrixF *fnmat[17];
44 //TMatrixD *fmatrix;
45 //TMatrixD *fnmat;
46 TMatrixF *fmatrix;
47 //TMatrixF *fnmat;
48 TMatrixF *fnmat[17];
49 //Int_t finmat[43][191];
50
51 //===============================================================================
52 bool Select( PamLevel2* event ){
53
54 //---------------------------------------------------------
55 // single track
56 //---------------------------------------------------------
57 if( event->GetTrkLevel2()->GetNTracks()!=1 ) return false;
58 PamTrack *track = event->GetTrack(0);
59 if(!track)return false;
60
61 //------------------------------------------------------------------
62 // tracker pre-selection
63 //------------------------------------------------------------------
64 TrkTrack *trk = track->GetTrkTrack();
65 float rigidity = trk->GetRigidity();
66 if ( CRIG ) rigidity = event->GetCaloLevel2()->qtot/260.;
67 if ( SRIG ) rigidity = event->GetGPamela()->P0;
68 bool TRACK__OK = false;
69 if(
70 trk->chi2 >0 &&
71 trk->GetNX()>=4 &&
72 trk->GetNY()>=3 &&
73 trk->GetLeverArmX()>=5 &&
74 true ) TRACK__OK = true;
75
76 if( !TRACK__OK )return false;
77
78 //------------------------------------------------------------------
79 // TOF pre-selection
80 //------------------------------------------------------------------
81 bool TOF__OK = false;
82 if(
83 event->GetToFLevel2()->GetNHitPaddles(0) == 1 &&
84 event->GetToFLevel2()->GetNHitPaddles(1) == 1 &&
85 event->GetToFLevel2()->GetNHitPaddles(2) == 1 &&
86 event->GetToFLevel2()->GetNHitPaddles(3) == 1 &&
87 event->GetToFLevel2()->GetNHitPaddles(4) >= 1 &&
88 event->GetToFLevel2()->GetNHitPaddles(5) >= 1 &&
89 event->GetToFLevel2()->npmt() <= 18 &&
90 !event->GetAcLevel2()->CARDhit() &&
91 !event->GetAcLevel2()->CAThit() &&
92 true ) TOF__OK = true;
93 if( !TOF__OK && !SIMU)return false;
94 //------------------------------------------------------
95 // no albedo
96 //------------------------------------------------------
97 if( !SIMU && (track->GetToFTrack()->beta[12]<=0.2 ||
98 track->GetToFTrack()->beta[12] >= 1.5) ) return false;
99
100 //------------------------------------------------------
101 bool CUT1 = false;
102 if(
103 trk->nstep<100 &&
104 rigidity<400. &&
105 rigidity>0.1 &&
106 trk->resx[0]<0.001 &&
107 trk->resx[5]<0.001 &&
108 track->IsSolved() &&
109 trk->IsInsideCavity() &&
110 true ) CUT1 = true;
111 //------------------------------------------------------
112 if( !CUT1 )return false;
113 if ( trk->GetDeflection()>0. && !SIMU ) return false;
114
115 //
116 // ELENA'S CUT
117 //
118 //
119 // lever-arm 6
120 //====================================================
121 bool LX6=false;
122 if(
123 track->GetTrkTrack()->GetLeverArmX()==6 &&
124 !track->GetTrkTrack()->IsBad(0,0) &&
125 !track->GetTrkTrack()->IsBad(5,0) &&
126 track->GetTrkTrack()->resx[0]<0.001 &&
127 track->GetTrkTrack()->resx[5]<0.001 &&
128 track->GetTrkTrack()->IsInsideCavity() &&
129 true ) LX6 = true;
130
131 //====================================================
132 // lever-arm 5
133 //====================================================
134 bool LX5=false;
135 if(
136 track->GetTrkTrack()->GetLeverArmX()==5 &&
137 true ){
138 if(
139 track->GetTrkTrack()->XGood(0) && track->GetTrkTrack()->XGood(4)
140 ){
141
142 if(
143 !track->GetTrkTrack()->IsBad(0,0) &&
144 !track->GetTrkTrack()->IsBad(4,0) &&
145 track->GetTrkTrack()->resx[0]<0.001 &&
146 track->GetTrkTrack()->resx[4]<0.001 &&
147 track->GetTrkTrack()->IsInsideCavity() &&
148 true) LX5 = true;
149 }else if (
150 track->GetTrkTrack()->XGood(1) && track->GetTrkTrack()->XGood(5)
151 ){
152
153 if(
154 !track->GetTrkTrack()->IsBad(1,0) &&
155 !track->GetTrkTrack()->IsBad(5,0) &&
156 track->GetTrkTrack()->resx[1]<0.001 &&
157 track->GetTrkTrack()->resx[5]<0.001 &&
158 track->GetTrkTrack()->IsInsideCavity() &&
159 true) LX5 = true;
160 }
161 }
162 if ( !LX5 && !LX6 ) return false;
163 Float_t defl = trk->GetDeflection();
164 float p0 = 1.111588e+00;
165 float p1 = 1.707656e+00;
166 float p2 = 1.489693e-01;
167 float chi2m025 = p0 + fabs(defl)*p1 + defl*defl*p2;
168
169 float def_0 = 0.07;
170 float chi2m025_0 = p0 + fabs(def_0)*p1 + def_0*def_0*p2;
171
172 // int nchi2cut=5;
173 float chi2cut=3.;
174 float chi2m = pow( chi2m025-chi2m025_0+pow(chi2cut,0.25), 4.);
175 bool CUT2 = false;
176 if(
177 track->GetTrkTrack()->chi2 < chi2m &&
178 true ) CUT2 = true;
179 if ( !CUT2 ) return false;
180 float dedxtrk = trk->GetDEDX();
181 // float zcutn = 9. + 20./(rigidity*rigidity);
182 float zcut2 = 3. + 4.3/(rigidity*rigidity);
183 float zcut1 = 0.52 + 0.455/(rigidity*rigidity);
184 Bool_t Z1 = false;
185 if(dedxtrk > zcut1 && dedxtrk < zcut2){
186 Z1=true;
187 }
188 if ( !Z1 && !SIMU ) return false;
189 //------------------------------------------------------
190 //
191 // energy momentum match
192 //
193 Float_t qtotimp = event->GetCaloLevel2()->qtot / trk->GetRigidity();
194 Float_t qcut2 = (-0.5 * trk->GetRigidity() + 150.) * 1.1;
195 if ( qcut2 < 55. ) qcut2 = 55.;
196 if ( qtotimp <= qcut2 ) return false;
197 //
198 for (Int_t i=0; i < 22; i++){
199 if ( track->GetCaloTrack()->tibar[i][1] < 0 || track->GetCaloTrack()->tibar[i][0] < 0 ){
200 return false;
201 };
202 };
203 //
204 if ( event->GetCaloLevel2()->qtot == 0. ) return false;
205 if ( rigidity>5. && track->GetCaloTrack()->qtrack/event->GetCaloLevel2()->qtot < 0.4 ) return false;
206 if ( rigidity<1. && track->GetToFTrack()->beta[12] < 0.8 ) return false;
207 if ( rigidity>50. ){
208 if ( trk->GetNX()<5 &&
209 trk->GetNY()<4 ) return false;
210 //
211 Bool_t sphit = false;
212 for ( Int_t plane = 0; plane < 6; plane++){
213 if ( !trk->XGood(plane) ){
214 for (Int_t sing = 0; sing < event->GetTrkLevel2()->nclsx(); sing++){
215 TClonesArray &t = *(event->GetTrkLevel2()->SingletX);
216 TrkSinglet *singlet = (TrkSinglet*)t[sing];
217 if ( (singlet->plane-1) == plane ){
218 Float_t x = (singlet->coord[0]+singlet->coord[1])/2.;
219 if ( fabs(track->GetTrkTrack()->xv[plane] - x) < 1. ) sphit = true;
220 };
221 };
222 };
223 if ( !trk->YGood(plane) ){
224 for (Int_t sing = 0; sing < event->GetTrkLevel2()->nclsy(); sing++){
225 TClonesArray &t = *(event->GetTrkLevel2()->SingletY);
226 TrkSinglet *singlet = (TrkSinglet*)t[sing];
227 if ( (singlet->plane-1) == plane ){
228 Float_t x1 = (singlet->coord[0]);
229 Float_t x2 = (singlet->coord[1]);
230 if ( fabs(track->GetTrkTrack()->yv[plane] - x1) < 1. ) sphit = true;
231 if ( fabs(track->GetTrkTrack()->yv[plane] - x2) < 1. ) sphit = true;
232 };
233 };
234 };
235 };
236 if ( sphit ) return false; // spurious hit along the track
237 };
238 //
239 Int_t ti0 = track->GetCaloTrack()->tibar[0][1]-1;
240
241 Int_t view = 0;
242 Int_t plane = 0;
243 Int_t strip = 0;
244 Float_t mip = 0.;
245 //
246 for ( Int_t i=0; i<event->GetCaloLevel1()->istrip; i++ ){
247 //
248 mip = event->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
249 if ( view == 1 && plane == 0 && strip == ti0 && mip > 4.) return false;
250 if ( view == 1 && (plane >0 || strip > ti0) ) break;
251 };
252 // if ( event->GetCaloLevel1()->qtotpl(0) > 7. ) return false;
253
254 // if ( rigidity > 2.2 || rigidity < 1.5 ) return false;
255 // printf(" rig %f CRIG %i SRIG %i \n",rigidity,CRIG,SRIG);
256 //
257 return true;
258 }
259 //===============================================================
260 // Create histograms
261 //
262 //
263 //
264 //
265 //
266 //===============================================================
267 void CreateHistos( PamLevel2* event , TString file){
268
269 cf = new CaloFranzini(event);
270 //
271 if ( MATRIX ){
272 cf->UpdateMatrixFile(file.Data());
273 cf->LoadBin();
274 if ( !FULL ){
275 cf->LoadLong();
276 } else {
277 cf->LoadFull();
278 };
279 } else {
280 cf->CreateMatrixFile(file.Data());
281 };
282 //
283 //
284 nbin = 18;
285 rig[0] = 0.1;
286 rig[1] = 0.5;
287 rig[2] = 1.;
288 rig[3] = 1.5;
289 rig[4] = 2.2;
290 rig[5] = 3.;
291 rig[6] = 4.;
292 rig[7] = 5.;
293 rig[8] = 6.;
294 rig[9] = 8.;
295 rig[10] = 10.;
296 rig[11] = 15.;
297 rig[12] = 25.;
298 rig[13] = 35.;
299 rig[14] = 50.;
300 rig[15] = 100.;
301 rig[16] = 200.;
302 rig[17] = 400.;
303 //
304 memset(rmean, 0, 17*sizeof(Float_t));
305 memset(ntot, 0, 17*sizeof(Int_t));
306 // memset(finmat, 0, 43*191*sizeof(Int_t));
307 //
308 for (Int_t i=0; i < 17 ; i++){
309 //for (Int_t i=3; i < 4 ; i++){
310 if ( !FULL ){
311 matrix[i] = new TMatrixD(43,43);
312 qplane[i] = new TArrayF(43);
313 nqplane[i] = new TArrayI(43);
314 nmat[i] = new TMatrixD(43,43);
315 } else {
316 if ( MATRIX ){
317 // fmatrix = new TMatrixF(4128,4128);
318 // fnmat = new TMatrixF(4128,4128);
319 // fmatrix = new TMatrixF(8213,8213);
320 // fnmat = new TMatrixF(8213,8213);
321 fmatrix = new TMatrixF(MDIM,MDIM);
322 // fnmat = new TMatrixF(MDIM,MDIM);
323 fnmat[i] = new TMatrixF(43,191);
324 // cf->WriteFullMatrix(fmatrix, i);
325 // cf->WriteFullNMatrix(fnmat, i);
326 // delete fmatrix;
327 // delete fnmat;
328 //fnmat[i] = new TMatrixI(8213,8213);
329 } else {
330 fqplane = new TMatrixD(43,191); // 43 planes x 191 strip (= 1 + 95 x 2, one strip is the one transversed by the track that could be on the extreme right or left)
331 fnqplane = new TMatrixD(43,191);//
332 //
333 cf->WriteFullMean(fqplane, i);
334 cf->WriteFullNMean(fnqplane, i);
335 delete fqplane;
336 delete fnqplane;
337 //
338 };
339 };
340 };
341 //
342 }
343
344 //===============================================================
345 void FindAverage( PamLevel2* L2, int iev ){
346 //
347 Float_t erig = L2->GetTrack(0)->GetTrkTrack()->GetRigidity();
348 if ( SRIG ) erig = L2->GetGPamela()->P0;
349 if ( CRIG ) erig = L2->GetCaloLevel2()->qtot/260.;
350 //
351 Int_t rbi = 0;
352 for (Int_t i = 0; i<nbin-1; i++){
353 if ( erig>=rig[i] && erig < rig[i+1] ){
354 rbi = i;
355 break;
356 };
357 };
358 //
359 if ( erig < rig[0] ) return;
360 if ( erig >= rig[nbin-1] ) return;
361 //
362 rmean[rbi] += erig;
363 ntot[rbi]++;
364 //
365 if (!FULL ){
366 Int_t dgf = 43;
367 //
368 for (Int_t i=0; i<dgf; i++){
369 (*nqplane[rbi])[i]++;
370 };
371 //
372 // Fill the estrip matrix
373 //
374 Int_t nplane = 0;
375 Int_t view = 0;
376 Int_t plane = 0;
377 Int_t strip = 0;
378 Float_t mip = 0.;
379 //
380 for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
381 //
382 mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
383 //
384 nplane = 1 - view + 2 * plane;
385 if ( erig > 4. && nplane == 0 && mip > 15. ) printf(" IEV %i erig %f OBT %u pkt %u file %s \n",iev,erig,L2->GetOrbitalInfo()->OBT,L2->GetOrbitalInfo()->pkt_num,L2->GetPamTree()->GetFile()->GetName());
386 //printf(" IEV %i OBT %u pkt %u file %s \n",iev,L2->GetOrbitalInfo()->OBT,L2->GetOrbitalInfo()->pkt_num,L2->GetPamTree()->GetFile()->GetName());
387 if ( nplane > 37 ) nplane--;
388 if ( nplane < dgf ){
389 (*qplane[rbi])[nplane] += mip;
390 };
391 //
392 };
393 } else {
394 //
395 // FULL CALORIMETER
396 //
397 fqplane = cf->LoadFullAverage(rbi);
398 fnqplane = cf->LoadFullNAverage(rbi);
399 CaloTrkVar *ct = L2->GetTrack(0)->GetCaloTrack();
400 //
401 Int_t nplane = 0;
402 Int_t view = 0;
403 Int_t plane = 0;
404 Int_t strip = 0;
405 Float_t mip = 0.;
406 //
407 Int_t cs = 0;
408 Int_t cd = 0;
409 Int_t mstrip = 0;
410 //
411 for (Int_t j=0; j<2; j++){
412 for (Int_t i=0; i<21; i++){
413 nplane = 1 - j + 2*i;
414 if ( nplane > 37 ) nplane--;
415 //
416 cs = ct->tibar[i][j] - 1;
417 //
418 cd = 95 - cs;
419 //
420 for (Int_t k=0; k<191; k++){
421 mstrip = cd + k;
422 // if ( mstrip < (191-cs) ) (*fnqplane[rbi])[nplane][mstrip] += 1.;
423 if ( mstrip < (191-cs) ) (*fnqplane)[nplane][mstrip] += 1.;
424 };
425 };
426 };
427 //
428 //
429 for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
430 //
431 mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
432 //
433 nplane = 1 - view + 2 * plane;
434 if ( nplane > 37 ) nplane--;
435 //
436 cs = ct->tibar[plane][view] - 1;
437 //
438 cd = 95 - cs;
439 //
440 mstrip = cd + strip;
441 //
442 // (*fqplane[rbi])[nplane][mstrip] += mip;
443 (*fqplane)[nplane][mstrip] += mip;
444 //
445 };
446 //
447 cf->WriteFullMean(fqplane, rbi);
448 cf->WriteFullNMean(fnqplane, rbi);
449 cf->UnLoadFullAverage(rbi);
450 cf->UnLoadFullNAverage(rbi);
451 delete fqplane;
452 delete fnqplane;
453 //
454 };
455 }
456
457 void CalculateAverage(){
458 //
459 if ( !FULL ){
460 for (Int_t i=0; i<nbin-1; i++){
461 if ( (*nqplane[i])[0] > 0 ) rmean[i] /= (Float_t)(*nqplane[i])[0];
462 for (Int_t j=0; j<43 ; j++){
463 if ( (*nqplane[i])[j] > 0 ){
464 (*qplane[i])[j] /= (Float_t)(*nqplane[i])[j];
465 } else {
466 (*qplane[i])[j] = 0.;
467 };
468 printf(" BIN %i plane %i average energy %f qplane %f nqplane %i \n",i,j,rmean[i],(*qplane[i])[j],(*nqplane[i])[j]);
469 };
470 };
471 for (Int_t i=0; i<nbin-1; i++){
472 //
473 cf->WriteLongMean(qplane[i], i);
474 //
475 };
476 } else {
477 //
478 for (Int_t i=0; i<nbin-1; i++){
479 fqplane = cf->LoadFullAverage(i);
480 fnqplane = cf->LoadFullNAverage(i);
481 if ( ntot[i] > 0 ) rmean[i] /= (Float_t)(ntot[i]);
482 //
483 for (Int_t j=0; j<43 ; j++){
484 for (Int_t k=0; k<191; k++){
485 // if ( (*fnqplane[i])[j][k] > 0 ){
486 // (*fqplane[i])[j][k] /= (Float_t)(*fnqplane[i])[j][k];
487 // } else {
488 // (*fqplane[i])[j][k] = 0.;
489 // };
490 // printf(" BIN %i plane %i strip %i average energy %f qplane %f nqplane %f \n",i,j,k,rmean[i],(*fqplane[i])[j][k],(*fnqplane[i])[j][k]);
491 if ( (*fnqplane)[j][k] > 0 ){
492 if ( (*fqplane)[j][k] == 0. ) (*fqplane)[j][k] = 0.7;
493 (*fqplane)[j][k] /= (Float_t)(*fnqplane)[j][k];
494 } else {
495 (*fqplane)[j][k] = 0.;
496 };
497 printf(" BIN %i plane %i strip %i average energy %f qplane %f nqplane %f \n",i,j,k,rmean[i],(*fqplane)[j][k],(*fnqplane)[j][k]);
498 };
499 };
500 cf->WriteFullMean(fqplane, i);
501 cf->WriteFullNMean(fnqplane, i);
502 cf->UnLoadFullAverage(i);
503 cf->UnLoadFullNAverage(i);
504 delete fqplane;
505 delete fnqplane;
506 };
507 //
508 // for (Int_t i=0; i<nbin-1; i++){
509 // //
510 // cf->WriteFullMean(fqplane[i], i);
511 // //
512 // };
513 };
514 //
515 cf->WriteNumBin(nbin);
516 //
517 TArrayF *rigbin = new TArrayF(18, rig);
518 cf->WriteRigBin(rigbin);
519 //
520 TArrayF *rmeanbin = new TArrayF(17, rmean);
521 TFile *file = cf->GetFile();
522 file->cd();
523 file->WriteObject(&(*rmeanbin), "binrigmean");
524 //
525 //
526 }
527
528 //===============================================================
529 void FindMatrix( PamLevel2* L2, int iev ){
530 //
531 Float_t erig = L2->GetTrack(0)->GetTrkTrack()->GetRigidity();
532 if ( SRIG ) erig = L2->GetGPamela()->P0;
533 if ( CRIG ) erig = L2->GetCaloLevel2()->qtot/260.;
534 //
535 Int_t rbi = 0;
536 for (Int_t i = 0; i<nbin-1; i++){
537 if ( erig>=rig[i] && erig < rig[i+1] ){
538 rbi = i;
539 break;
540 };
541 };
542 //
543 if ( rbi != 3 ) return;
544 if ( erig < rig[0] ) return;
545 if ( erig >= rig[nbin-1] ) return;
546 //
547 if ( !FULL ){
548 Int_t dgf = 43;
549 //
550 for (Int_t i=0; i<dgf; i++){
551 for (Int_t j=0; j<dgf; j++){
552 (*nmat[rbi])[i][j] += 1.;
553 };
554 };
555 //
556 // Fill the estrip matrix
557 //
558 Int_t nplane = 0;
559 Int_t view = 0;
560 Int_t plane = 0;
561 Int_t strip = 0;
562 Float_t mip = 0.;
563 Float_t hpl[43];
564 memset(hpl,0,43*sizeof(Float_t));
565 for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
566 //
567 mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
568 //
569 nplane = 1 - view + 2 * plane;
570 if ( nplane > 37 ) nplane--;
571 if ( nplane < dgf ){
572 hpl[nplane] += mip;
573 };
574 //
575 };
576 //
577 for (Int_t i=0; i<dgf; i++){
578 for (Int_t j=0; j<dgf; j++){
579 (*matrix[rbi])[i][j] += (hpl[i] - cf->GetAverageAt(i,erig)) * (hpl[j] - cf->GetAverageAt(j,erig));
580 };
581 };
582 } else {
583 //
584 // FULL CALORIMETER
585 //
586 printf(" Retrieve matrix %i IEV %i \n",rbi,iev);
587 // fmatrix = cf->LoadFullMatrix(rbi);
588 // cf->LoadFullMatrix(rbi,fmatrix);
589 // fnmat = cf->LoadFullNMatrix(rbi);
590 printf(" done \n");
591 printf(" start loop \n");
592 //
593 CaloTrkVar *ct = L2->GetTrack(0)->GetCaloTrack();
594 //
595 Int_t nplane = 0;
596 Int_t view = 0;
597 Int_t plane = 0;
598 Int_t strip = 0;
599 Float_t mip = 0.;
600 //
601 // Int_t mindgf = 48;
602 // Int_t dgf = 143;
603 Int_t mindgf = 0;
604 Int_t dgf = 191;
605 // Int_t mindgf = 85;
606 // Int_t dgf = 115;
607 Int_t cs = 0;
608 Int_t cd = 0;
609 Int_t mstrip = 0;
610 //
611 Float_t mipv[43][191];
612 memset(mipv,0,43*191*sizeof(Float_t));
613 //
614 for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
615 //
616 mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
617 //
618 nplane = 1 - view + 2 * plane;
619 if ( nplane > 37 ) nplane--;
620 //
621 cs = ct->tibar[plane][view] - 1;
622 //
623 cd = 95 - cs;
624 //
625 mstrip = cd + strip;
626 //
627 mipv[nplane][mstrip] = mip;
628 //
629 };
630 //
631 Float_t mip1 = 1.;
632 Int_t cs1;
633 Int_t cd1;
634 Float_t mip2 = 1.;
635 Int_t cs2;
636 Int_t cd2;
637 Int_t mi = -1;
638 Int_t mj = -1;
639 Int_t nn1 = 0;
640 Int_t pl1 = 0;
641 Int_t vi1 = 0;
642 Int_t nn2 = 0;
643 Int_t pl2 = 0;
644 Int_t vi2 = 0;
645 Int_t mstrip1min = 0;
646 Int_t mstrip1max = 0;
647 Int_t mstrip2min = 0;
648 Int_t mstrip2max = 0;
649 //
650 Int_t toto = 0;
651 //
652 for (Int_t nplane1=0; nplane1<43; nplane1++){
653 if ( nplane1 >= 37 ) nn1 = nplane1 + 1;
654 vi1 = 1;
655 if ( nn1%2 ) vi1 = 0;
656 pl1 = (nn1 - 1 + vi1)/2;
657 //
658 cs1 = ct->tibar[pl1][vi1] - 1; // convertire nplane in pl1 e vi1
659 //
660 cd1 = 95 - cs1;
661 //
662 mstrip1min = TMath::Max(mindgf,(cd1+0));
663 mstrip1max = TMath::Min(dgf,(cd1+95)) + 1;
664 //
665 if ( nplane1 == 0 || nplane1 == 42 ) printf(" pl %i mstrip1min %i mstrip1max %i \n",nplane1,mstrip1min,mstrip1max);
666 //
667 for (Int_t mstrip1=mstrip1min; mstrip1<mstrip1max; mstrip1++){
668 // printf(".\n");
669 //
670 mj = -1;
671 //
672 mip1 = mipv[nplane1][mstrip1] - cf->GetFullAverageAt(nplane1,mstrip1,erig,rbi);
673 //
674 mi = (nplane1 * 191) + mstrip1;
675 //
676 // if ( mstrip1 > mstrip1min ) break;
677 // if ( mstrip1 > dgf ) break;
678 // if ( mstrip1 >= mindgf && mstrip1 <= dgf && mstrip1 >= mstrip1min && mstrip1 <= mstrip1max ){
679 //
680 // finmat[nplane1][mstrip1]++;
681 (*fnmat[rbi])[nplane1][mstrip1] += 1.;
682 //
683 if ( mip1 != 0. ){
684 //
685 for (Int_t nplane2=0; nplane2<43; nplane2++){
686 //
687 if ( nplane2 >= 37 ) nn2 = nplane2 + 1;
688 vi2 = 1;
689 if ( nn2%2 ) vi2 = 0;
690 pl1 = (nn2 - 1 + vi2)/2;
691 //
692 cs2 = ct->tibar[pl2][vi2] - 1;
693 //
694 cd2 = 95 - cs2;
695 //
696 // mstrip2min = cd2 + 0;
697 // mstrip2max = cd2 + 95;
698 mstrip2min = TMath::Max(mindgf,(cd2+0));
699 mstrip2max = TMath::Min(dgf,(cd2+95)) + 1;
700 //
701 if ( nplane1 == 0 && nplane2 == 0 && mstrip1==mstrip1min ) printf(" mstrip2min %i mstrip2max %i \n",mstrip2min,mstrip2max);
702 //
703 for (Int_t mstrip2=mstrip2min; mstrip2<mstrip2max; mstrip2++){
704 //
705 mip2 = mipv[nplane2][mstrip2] - cf->GetFullAverageAt(nplane2,mstrip2,erig,rbi);
706 //
707 if ( mip2 != 0. ){
708 //
709 mj = (nplane2 * 191) + mstrip2;
710 // mj++;
711 //
712 // if ( mstrip2 > mstrip2min ) break;
713 // if ( mstrip2 > dgf ) break;
714 // if ( mstrip2 >= mindgf && mstrip2 <= dgf && mstrip2 >= mstrip2min && mstrip2 <= mstrip2max ){
715 // if ( mstrip1 >= mstrip1min && mstrip1 <= mstrip1max && mstrip2 >= mstrip2min && mstrip2 <= mstrip2max){
716 // (*fmatrix[rbi])[mi][mj] += (mipv[nplane1][mstrip1] - cf->GetFullAverageAt(nplane1,mstrip1,erig)) * (mipv[nplane2][mstrip2] - cf->GetFullAverageAt(nplane2,mstrip2,erig));
717 // (*fnmat[rbi])[mi][mj] += 1.;
718 (*fmatrix)[mi][mj] += (mip1 * mip2); // giusto
719 toto++;
720 // (*fmatrix)[mi][mj] += 1.;
721 // cf->GetFullAverageAt(nplane1,mstrip1,erig,rbi);
722 // cf->GetFullAverageAt(nplane2,mstrip2,erig,rbi);
723 // (*fnmat)[mi][mj] += 1.;
724 // };
725 };
726 };
727 };
728 };
729 };
730 };
731 //
732 printf(" toto = %i \n",toto);
733 printf("\n done \n");
734 printf(" write matrix \n");
735 // cf->WriteFullMatrix(fmatrix, rbi);
736 // cf->WriteFullNMatrix(fnmat, rbi);
737 printf(" done \n");
738 printf(" unload matrix \n");
739 // cf->UnLoadFullMatrix(rbi);
740 // cf->UnLoadFullNMatrix(rbi);
741 printf(" done \n");
742 printf(" delete matrix \n");
743 // delete fmatrix;
744 // delete fnmat;
745 printf(" done \n");
746 };
747 }
748
749 //===============================================================
750 // Save histograms
751 //
752 //
753 //
754 //
755 //
756 //===============================================================
757 void SaveHistos(){
758 //
759 if ( MATRIX ){
760 //
761 printf("Finished, calculating average and inverting matrices\n");
762 //
763 if ( !FULL ){
764 for (Int_t i=0; i<nbin-1; i++){
765 //
766 // determine the average matrix
767 //
768 for (Int_t ii=0; ii<43; ii++){
769 for (Int_t j=0; j<43; j++){
770 if ( (*nmat[i])[ii][j] > 0. ){
771 (*matrix[i])[ii][j] /= (*nmat[i])[ii][j];
772 } else {
773 (*matrix[i])[ii][j] = 0.;
774 };
775 };
776 };
777 //
778 cf->WriteLongMatrix(matrix[i],i);
779 //
780 if ( matrix[i]->Determinant() == 0. ){
781 printf("\n");
782 for (Int_t ii=0; ii<43; ii++){
783 for (Int_t j=0; j<43; j++){
784 printf(" %.f",(*matrix[i])[ii][j]);
785 };
786 printf("\n");
787 };
788 printf("\n");
789 printf(" ERROR: the matrix at bin %i is singular, determinant = 0., it cannot be inverted! \n",i);
790 } else {
791 Double_t det = 0.;
792 TMatrixD invmatrix = (TMatrixD)(matrix[i]->Invert(&det));
793 printf(" Bin %i determinant is %f \n",i,det);
794 cf->WriteInvertedLongMatrix((TMatrixD)invmatrix,i);
795 };
796 };
797 } else {
798 //
799 // FULL
800 //
801 // for (Int_t i=0; i<nbin-1; i++){
802 // for (Int_t i=3; i<5; i++){
803 for (Int_t i=3; i<4; i++){
804 //
805 // determine the average matrix
806 //
807 // fmatrix = cf->LoadFullMatrix(i);
808 // fnmat = cf->LoadFullNMatrix(i);
809 //
810 // for (Int_t ii=0; ii<MDIM; ii++){
811 // for (Int_t j=0; j<MDIM; j++){
812 // // if ( (*fnmat[i])[ii][j] > 0. ){
813 // // (*fmatrix[i])[ii][j] /= (*fnmat[i])[ii][j];
814 // // } else {
815 // // (*fmatrix[i])[ii][j] = 0.;
816 // // };
817 // if ( (*fnmat)[ii][j] > 0. ){
818 // (*fmatrix)[ii][j] /= (*fnmat)[ii][j];
819 // } else {
820 // (*fmatrix)[ii][j] = 0.;
821 // };
822 // };
823 // };
824 //
825 Int_t i1 = -1;
826 Int_t j1 = -1;
827 Int_t nonzero = 0;
828 Int_t nonzero1 = 0;
829 for (Int_t ii=0; ii<43; ii++){
830 for (Int_t j=0; j<191; j++){
831 // if ( (*fnmat[i])[ii][j] > 0. ){
832 // (*fmatrix[i])[ii][j] /= (*fnmat[i])[ii][j];
833 // } else {
834 // (*fmatrix[i])[ii][j] = 0.;
835 // };
836 i1 = (ii * 191) + j;
837 // j1 = -1;
838 for (Int_t iij=0; iij<43; iij++){
839 for (Int_t jj=0; jj<191; jj++){
840 //
841 j1 = (iij * 191) + jj;
842 // j1++;
843 // if ( finmat[ii][j] > 0 ){
844 // (*fmatrix)[i1][j1] /= finmat[ii][j];
845 if ( (*fnmat[i])[ii][j] == 0. || (*fmatrix)[i1][j1] == 0. || !((*fmatrix)[i1][j1] == (*fmatrix)[i1][j1]) ){
846 (*fmatrix)[i1][j1] = 0.;
847 } else {
848 (*fmatrix)[i1][j1] /= (*fnmat[i])[ii][j];
849 nonzero++;
850 if ( i1 == 0 ) nonzero1++;
851 };
852 };
853 };
854 };
855 };
856 //
857 printf(" Matrix has %i non-zero elements \n",nonzero);
858 printf(" Matrix has %i non-zero elements on the first row\n",nonzero1);
859 //
860 // Bool_t BAD = false;
861 // for (Int_t ii=0; ii<43; ii++){
862 // for (Int_t j=0; j<191; j++){
863 // //
864 // i1 = (ii * 191) + j;
865 // //
866 // for (Int_t iij=0; iij<43; iij++){
867 // for (Int_t jj=0; jj<191; jj++){
868 // //
869 // j1 = (iij * 191) + jj;
870 // //
871 // // printf(" ROW %i COLUMN %i VALUE %f \n",i1,j1,(*fmatrix)[i1][j1]);
872 // if ( (*fmatrix)[i1][j1] == 0. || !((*fmatrix)[i1][j1]==(*fmatrix)[i1][j1]) ){
873 // printf(" ROW %i COLUMN %i VALUE %f \n",i1,j1,(*fmatrix)[i1][j1]);
874 // printf(" che schifo! \n");
875 // BAD = true;
876 // };
877 // //
878 // };
879 // };
880 // };
881 // };
882 // //
883 // if ( BAD ) printf(" questa matrice fa cagare \n");
884 //
885 //
886 // cf->WriteFullMatrix(fmatrix[i],i);
887 cf->WriteFullMatrix(fmatrix, i);
888 // cf->WriteFullNMatrix(fnmat, i);
889 cf->WriteFullNMatrix(fnmat[i], i);
890 //
891 // if ( fmatrix[i]->Determinant() == 0. ){
892 if ( fmatrix->Determinant() == 0. ){
893 printf(" ERROR: the matrix at bin %i is singular, determinant = 0., it cannot be inverted! \n",i);
894 } else {
895 Double_t det = 0.;
896 // TMatrixF invmatrix = (TMatrixF)(fmatrix[i]->Invert(&det));
897 // printf(" Bin %i determinant is %f \n",i,det);
898 // cf->WriteInvertedFullMatrix((TMatrixF)invmatrix,i);
899 TMatrixF invmatrix = (TMatrixF)(fmatrix->Invert(&det));
900 printf(" Bin %i determinant is %f \n",i,det);
901 cf->WriteInvertedFullMatrix((TMatrixF)invmatrix,i);
902 };
903 //
904 cf->UnLoadFullMatrix(i);
905 // cf->UnLoadFullNMatrix(i);
906 delete fmatrix;
907 // delete fnmat;
908 //
909 };
910 };
911 //
912 printf(" done, closing file and exiting\n");
913 //
914 };
915 //
916 cf->CloseMatrixFile();
917 //
918 cf->Delete();
919 //
920 }

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