1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 ***************************************************************************/
18 Revision 1.17 2007/06/06 16:26:46 arcelli
19 remove fall-back call to local CDB storage
21 Revision 1.16 2007/05/15 16:25:44 cvetan
22 Moving the alignment-related static methods from AliAlignObj to the new geometry steering class AliGeomManager (macro from Raffaele)
24 Revision 1.15 2007/05/03 09:25:10 decaro
25 Coding convention: RN13 violation -> suppression
27 Revision 1.14 2007/04/18 14:49:54 arcelli
28 Some code cleanup, added more debug info
30 Revision 1.13 2007/04/17 16:38:36 arcelli
31 Include Methods to derive TOF AlignObjs from Survey Data
33 Revision 1.12 2007/02/28 18:09:23 arcelli
34 Add protection against failed retrieval of the CDB cal object
36 Revision 1.11 2006/09/19 14:31:26 cvetan
37 Bugfixes and clean-up of alignment object classes. Introduction of so called symbolic names used to identify the alignable volumes (Raffaele and Cvetan)
39 Revision 1.10 2006/08/22 13:26:05 arcelli
40 removal of effective c++ warnings (C.Zampolli)
42 Revision 1.9 2006/08/10 14:46:54 decaro
43 TOF raw data format: updated version
45 Revision 1.8 2006/05/04 19:41:42 hristov
46 Possibility for partial TOF geometry (S.Arcelli)
48 Revision 1.7 2006/04/27 13:13:29 hristov
49 Moving the destructor to the implementation file
51 Revision 1.6 2006/04/20 22:30:49 hristov
52 Coding conventions (Annalisa)
54 Revision 1.5 2006/04/16 22:29:05 hristov
55 Coding conventions (Annalisa)
57 Revision 1.4 2006/04/05 08:35:38 hristov
58 Coding conventions (S.Arcelli, C.Zampolli)
60 Revision 1.3 2006/03/31 13:49:07 arcelli
61 Removing some junk printout
63 Revision 1.2 2006/03/31 11:26:30 arcelli
64 changing CDB Ids according to standard convention
66 Revision 1.1 2006/03/28 14:54:48 arcelli
67 class for TOF alignment
69 author: Silvia Arcelli, arcelli@bo.infn.it
72 /////////////////////////////////////////////////////////
74 // Class for alignment procedure //
78 /////////////////////////////////////////////////////////
87 #include "AliAlignObj.h"
88 #include "AliAlignObjParams.h"
89 #include "AliAlignObjMatrix.h"
90 #include "AliCDBManager.h"
91 #include "AliCDBMetaData.h"
93 #include "AliCDBEntry.h"
94 #include "AliTOFAlignment.h"
97 ClassImp(AliTOFAlignment)
98 const Double_t AliTOFAlignment::fgkXsizeTOF = 124.5; // x size of the TOF ext. volume, cm
99 const Double_t AliTOFAlignment::fgkYsizeTOF = 29.0; // y size of the TOF ext. volume, cm
100 const Double_t AliTOFAlignment::fgkZsizeTOF = 913.8; // z size of the TOF ext. volume, cm
101 const Double_t AliTOFAlignment::fgkRorigTOF = 384.5; // Mean Radius of the TOF ext. volume, cm
102 const Double_t AliTOFAlignment::fgkXFM = 38.0; //x pos of FM in the LRS, cm
103 const Double_t AliTOFAlignment::fgkYFM = 11.2; //y pos of FM in the LRS, cm
104 const Double_t AliTOFAlignment::fgkZFM = 457.3;//z pos of FM in the LRS, cm
105 const Double_t AliTOFAlignment::fgkZsizeTOFSens=741.2; //z size of the TOF sensitive volume, cm
107 //_____________________________________________________________________________
108 AliTOFAlignment::AliTOFAlignment():
109 TTask("AliTOFAlignment",""),
112 fTOFAlignObjArray(0x0)
114 //AliTOFalignment main Ctor
115 for(Int_t ism=0;ism<18;ism++){
116 for(Int_t iFM=0;iFM<4;iFM++){
117 for(Int_t iFMc=0;iFMc<3;iFMc++){
118 fTOFSurveyFM[ism][iFM][iFMc]=-1.;
123 //_____________________________________________________________________________
124 AliTOFAlignment::AliTOFAlignment(const AliTOFAlignment &t):
125 TTask("AliTOFAlignment",""),
128 fTOFAlignObjArray(0x0)
130 //AliTOFAlignment copy Ctor
132 fNTOFAlignObj=t.fNTOFAlignObj;
133 fTOFAlignObjArray=t.fTOFAlignObjArray;
134 //AliTOFalignment main Ctor
135 for(Int_t iSM=0;iSM<18;iSM++){
136 for(Int_t iFM=0;iFM<4;iFM++){
137 for(Int_t iFMc=0;iFMc<3;iFMc++){
138 fTOFSurveyFM[iSM][iFM][iFMc]=-1.;
143 //_____________________________________________________________________________
144 AliTOFAlignment& AliTOFAlignment::operator=(const AliTOFAlignment &t){
145 //AliTOFAlignment assignment operator
147 this->fNTOFAlignObj=t.fNTOFAlignObj;
148 this->fTOFmgr=t.fTOFmgr;
149 this->fTOFAlignObjArray=t.fTOFAlignObjArray;
153 //_____________________________________________________________________________
154 AliTOFAlignment::~AliTOFAlignment() {
155 delete fTOFAlignObjArray;
159 //_____________________________________________________________________________
160 void AliTOFAlignment::Smear( Float_t *tr, Float_t *rot)
162 //Introduce Random Offset/Tilts
163 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
164 Float_t dx, dy, dz; // shifts
165 Float_t dpsi, dtheta, dphi; // angular displacements
166 TRandom *rnd = new TRandom(1567);
169 AliGeomManager::ELayerID iLayer = AliGeomManager::kInvalidLayer;
170 UShort_t iIndex=0; //dummy volume index
171 // AliGeomManager::ELayerID iLayer = AliGeomManager::kTOF;
172 // Int_t iIndex=1; //dummy volume index
173 UShort_t dvoluid = AliGeomManager::LayerToVolUID(iLayer,iIndex); //dummy volume identity
175 for (i = 0; i<nSMTOF ; i++) {
177 sprintf(path,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",i,i);
179 dx = (rnd->Gaus(0.,1.))*tr[0];
180 dy = (rnd->Gaus(0.,1.))*tr[1];
181 dz = (rnd->Gaus(0.,1.))*tr[2];
185 AliAlignObjParams *o =new AliAlignObjParams(path, dvoluid, dx, dy, dz, dpsi, dtheta, dphi, kTRUE);
186 fTOFAlignObjArray->Add(o);
189 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
190 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
194 //_____________________________________________________________________________
195 void AliTOFAlignment::Align( Float_t *tr, Float_t *rot)
197 //Introduce Offset/Tilts
199 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
200 Float_t dx, dy, dz; // shifts
201 Float_t dpsi, dtheta, dphi; // angular displacements
205 AliGeomManager::ELayerID iLayer = AliGeomManager::kInvalidLayer;
206 UShort_t iIndex=0; //dummy volume index
207 UShort_t dvoluid = AliGeomManager::LayerToVolUID(iLayer,iIndex); //dummy volume identity
209 for (i = 0; i<nSMTOF ; i++) {
212 sprintf(path,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",i,i);
220 AliAlignObjParams *o =new AliAlignObjParams(path, dvoluid, dx, dy, dz, dpsi, dtheta, dphi, kTRUE);
221 fTOFAlignObjArray->Add(o);
223 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
224 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
226 //_____________________________________________________________________________
227 void AliTOFAlignment::WriteParOnCDB(Char_t *sel, Int_t minrun, Int_t maxrun)
229 //Write Align Par on CDB
230 AliCDBManager *man = AliCDBManager::Instance();
231 Char_t *sel1 = "AlignPar" ;
233 sprintf(out,"%s/%s",sel,sel1);
234 AliCDBId idTOFAlign(out,minrun,maxrun);
235 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
236 mdTOFAlign->SetResponsible("TOF");
237 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
238 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
240 //_____________________________________________________________________________
241 void AliTOFAlignment::ReadParFromCDB(Char_t *sel, Int_t nrun)
243 //Read Align Par from CDB
244 AliCDBManager *man = AliCDBManager::Instance();
245 Char_t *sel1 = "AlignPar" ;
247 sprintf(out,"%s/%s",sel,sel1);
248 AliCDBEntry *entry = man->Get(out,nrun);
250 AliError(Form("Failed to get entry: %s",out));
253 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
254 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
255 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
258 //_____________________________________________________________________________
259 void AliTOFAlignment::WriteSimParOnCDB(Char_t *sel, Int_t minrun, Int_t maxrun)
261 //Write Sim Align Par on CDB
262 AliCDBManager *man = AliCDBManager::Instance();
263 Char_t *sel1 = "AlignSimPar" ;
265 sprintf(out,"%s/%s",sel,sel1);
266 AliCDBId idTOFAlign(out,minrun,maxrun);
267 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
268 mdTOFAlign->SetResponsible("TOF");
269 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
270 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
272 //_____________________________________________________________________________
273 void AliTOFAlignment::ReadSimParFromCDB(Char_t *sel, Int_t nrun){
274 //Read Sim Align Par from CDB
275 AliCDBManager *man = AliCDBManager::Instance();
276 Char_t *sel1 = "AlignSimPar" ;
278 sprintf(out,"%s/%s",sel,sel1);
279 AliCDBEntry *entry = man->Get(out,nrun);
280 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
281 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
282 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
285 //_____________________________________________________________________________
286 void AliTOFAlignment::WriteOnCDBforDC()
288 //Write Align Par on CDB for DC06
289 AliCDBManager *man = AliCDBManager::Instance();
290 AliCDBId idTOFAlign("TOF/Align/Data",0,0);
291 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
292 mdTOFAlign->SetComment("Alignment objects for ideal geometry, i.e. applying them to TGeo has to leave geometry unchanged");
293 mdTOFAlign->SetResponsible("TOF");
294 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
295 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
297 //_____________________________________________________________________________
298 void AliTOFAlignment::ReadFromCDBforDC()
300 //Read Sim Align Par from CDB for DC06
301 AliCDBManager *man = AliCDBManager::Instance();
302 AliCDBEntry *entry = man->Get("TOF/Align/Data",0);
303 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
304 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
305 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
308 //_____________________________________________________________________________
309 void AliTOFAlignment::BuildGeomForSurvey()
312 //Generates the ideal TOF structure with four Fiducial Marks in each
313 //supermodule (two on each z side) in their expected position.
314 //Highly inspired to Raffaele's example...
316 fTOFmgr = new TGeoManager("Geom","survey to alignment for TOF");
317 TGeoMedium *medium = 0;
318 TGeoVolume *top = fTOFmgr->MakeBox("TOP",medium,1000,1000,1000);
319 fTOFmgr->SetTopVolume(top);
320 // make shape components:
321 // This is the big box containing the TOF master sensitive volume+services
322 TGeoBBox *sbox0 = new TGeoBBox(fgkXsizeTOF*0.5,fgkYsizeTOF*0.5,fgkZsizeTOF*0.5);
323 TGeoVolume* box0[18];
324 // This is the big box containing the TOF master sensitive volume
325 TGeoBBox *sbox1 = new TGeoBBox(fgkXsizeTOF*0.5,fgkYsizeTOF*0.5,fgkZsizeTOFSens*0.5);
326 TGeoVolume* box1 = new TGeoVolume("B1",sbox1);
327 box1->SetLineColor(3);//green
329 // Now four fiducial marks on SM, expressed in local coordinates
330 // They are positioned at x=+/- 38 cm, y=11.2, z=+/- 456.94 cm
332 TGeoBBox *fmbox = new TGeoBBox(1,1,1);
333 TGeoVolume* fm = new TGeoVolume("FM",fmbox);
334 fm->SetLineColor(2);//color
336 TGeoTranslation* mAtr = new TGeoTranslation("mAtr",-fgkXFM, fgkYFM ,fgkZFM);
337 TGeoTranslation* mBtr = new TGeoTranslation("mBtr", fgkXFM, fgkYFM, fgkZFM);
338 TGeoTranslation* mCtr = new TGeoTranslation("mCtr", fgkXFM, fgkYFM,-fgkZFM);
339 TGeoTranslation* mDtr = new TGeoTranslation("mDtr",-fgkXFM, fgkYFM,-fgkZFM);
341 // position all this stuff in the global ALICE frame
347 Float_t smR = fgkRorigTOF;
349 for (Int_t iSM = 0; iSM < 18; iSM++) {
350 Int_t mod = iSM + 13;
351 if (mod > 17) mod -= 18;
352 sprintf(name, "BTOF%d",mod);
353 box0[iSM] = new TGeoVolume(name,sbox0);
354 Float_t phi = iSM * 20.;
355 Float_t phirot = 180 + phi;
356 smX = TMath::Sin(phi*TMath::Pi()/180.)*smR;
357 smY = -TMath::Cos(phi*TMath::Pi()/180.)*smR;
359 TGeoRotation* smRot = new TGeoRotation("smRot",phirot,0,0.);
360 TGeoCombiTrans trans = *(new TGeoCombiTrans(smX,smY,smZ, smRot));
361 TGeoMatrix* id = new TGeoHMatrix();
362 TGeoHMatrix transMat = *id * trans;
363 TGeoHMatrix *smTrans = new TGeoHMatrix(transMat);
364 box0[iSM]->SetVisDaughters();
365 box0[iSM]->SetLineColor(1); //black
366 top->AddNode(box0[iSM],1,smTrans); //place the extended SM volume
367 box0[iSM]->AddNode(box1,1); //place the inner SM volume
368 box0[iSM]->AddNode(fm,1,mAtr);
369 box0[iSM]->AddNode(fm,2,mBtr);
370 box0[iSM]->AddNode(fm,3,mCtr);
371 box0[iSM]->AddNode(fm,4,mDtr);
374 fTOFmgr->CloseGeometry();
375 fTOFmgr->GetTopVolume()->Draw();
376 fTOFmgr->SetVisOption(0);
377 fTOFmgr->SetVisLevel(6);
379 // Now Store the "Ideal" Matrices for later use....
381 for (Int_t iSM = 0; iSM < 18; iSM++) {
383 sprintf(name, "TOP_1/BTOF%d_1", iSM);
384 printf("\n\n***************** TOF SuperModule: %s ****************** \n",name);
385 TGeoPhysicalNode* pn3 = fTOFmgr->MakePhysicalNode(name);
386 fTOFMatrixId[iSM] = pn3->GetMatrix(); //save "ideal" global matrix
387 printf("\n\n*************** The Ideal Matrix in GRS *****************\n");
388 fTOFMatrixId[iSM]->Print();
392 //_____________________________________________________________________________
393 void AliTOFAlignment::InsertMisAlignment( Float_t *mis)
395 // Now Apply the Displacements and store the misaligned FM positions...
397 Double_t lA[3]={-fgkXFM,fgkYFM, fgkZFM};
398 Double_t lB[3]={ fgkXFM,fgkYFM, fgkZFM};
399 Double_t lC[3]={ fgkXFM,fgkYFM,-fgkZFM};
400 Double_t lD[3]={-fgkXFM,fgkYFM,-fgkZFM};
402 for(Int_t iSM=0;iSM<18;iSM++){
403 // ************* get ideal global matrix *******************
405 sprintf(name, "TOP_1/BTOF%d_1", iSM);
407 printf("\n\n******Misaligning TOF SuperModule ************** %s \n",name);
409 // ************* get ideal local matrix *******************
410 TGeoHMatrix g3 = *fTOFmgr->GetCurrentMatrix();
411 TGeoNode* n3 = fTOFmgr->GetCurrentNode();
412 TGeoMatrix* l3 = n3->GetMatrix();
414 Double_t gA[3], gB[3], gC[3], gD[3]; // ideal FM point coord., global RS
415 g3.LocalToMaster(lA,gA);
416 g3.LocalToMaster(lB,gB);
417 g3.LocalToMaster(lC,gC);
418 g3.LocalToMaster(lD,gD);
421 // We apply a delta transformation to the surveyed vol to represent
422 // its real position, given below by ng3 nl3, which differs from its
423 // ideal position saved above in g3 and l3
426 Double_t dx = mis[0]; // shift along x
427 Double_t dy = mis[1]; // shift along y
428 Double_t dz = mis[2]; // shift along z
429 Double_t dphi = mis[3]; // rot around z
430 Double_t dtheta = mis[4]; // rot around x'
431 Double_t dpsi = mis[5]; // rot around z'
433 TGeoRotation* rrot = new TGeoRotation("rot",dphi,dtheta,dpsi);
434 TGeoCombiTrans localdelta = *(new TGeoCombiTrans(dx,dy,dz, rrot));
435 // new local matrix, representing real position
436 TGeoHMatrix nlocal = *l3 * localdelta;
437 TGeoHMatrix* nl3 = new TGeoHMatrix(nlocal);
438 TGeoPhysicalNode* pn3 = fTOFmgr->MakePhysicalNode(name);
440 pn3->Align(nl3); //Align....
442 TGeoHMatrix* ng3 = pn3->GetMatrix(); //"real" global matrix, what survey sees
443 printf("\n\n************* The Misaligned Matrix in GRS **************\n");
445 Double_t ngA[3], ngB[3], ngC[3], ngD[3];// real FM point coord., global RS
446 ng3->LocalToMaster(lA,ngA);
447 ng3->LocalToMaster(lB,ngB);
448 ng3->LocalToMaster(lC,ngC);
449 ng3->LocalToMaster(lD,ngD);
451 for(Int_t iFM=0;iFM<3;iFM++){
452 fTOFSurveyFM[iSM][0][iFM]=ngA[iFM];
453 fTOFSurveyFM[iSM][1][iFM]=ngB[iFM];
454 fTOFSurveyFM[iSM][2][iFM]=ngC[iFM];
455 fTOFSurveyFM[iSM][3][iFM]=ngD[iFM];
460 //_____________________________________________________________________________
461 void AliTOFAlignment::AlignFromSurvey()
463 //From Survey data, derive the needed transformations to get the
465 //Again, highly "inspired" to Raffaele's example...
467 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
468 Int_t index=0; //let all SM modules have index=0
469 AliGeomManager::ELayerID layer = AliGeomManager::kInvalidLayer;
470 UShort_t dvoluid = AliGeomManager::LayerToVolUID(layer,index); //dummy vol id
472 for(Int_t iSM=0;iSM<18;iSM++){
474 printf("\n\n******Survey analysis for TOF SuperModule ************** %i \n",iSM);
476 Double_t ngA[3], ngB[3], ngC[3], ngD[3];// real FM point coord., global RS
478 // Get the 'realistic' input from the Survey Matrix
479 for(Int_t iFM=0;iFM<3;iFM++){
480 ngA[iFM]= fTOFSurveyFM[iSM][0][iFM];
481 ngB[iFM]= fTOFSurveyFM[iSM][1][iFM];
482 ngC[iFM]= fTOFSurveyFM[iSM][2][iFM];
483 ngD[iFM]= fTOFSurveyFM[iSM][3][iFM];
486 // From the new fiducial marks coordinates derive back the
487 // new global position of the surveyed volume
488 //*** What follows is the actual survey-to-alignment procedure
490 Double_t ab[3], bc[3], n[3];
491 Double_t plane[4], s=1.;
493 // first vector on the plane of the fiducial marks
494 for(Int_t i=0;i<3;i++){
495 ab[i] = (ngB[i] - ngA[i]);
498 // second vector on the plane of the fiducial marks
499 for(Int_t i=0;i<3;i++){
500 bc[i] = (ngC[i] - ngB[i]);
503 // vector normal to the plane of the fiducial marks obtained
504 // as cross product of the two vectors on the plane d0^d1
505 n[0] = (ab[1] * bc[2] - ab[2] * bc[1]);
506 n[1] = (ab[2] * bc[0] - ab[0] * bc[2]);
507 n[2] = (ab[0] * bc[1] - ab[1] * bc[0]);
509 Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
511 s = Double_t(1.)/sizen ; //normalization factor
513 AliInfo("Problem in normalizing the vector");
516 // plane expressed in the hessian normal form, see:
517 // http://mathworld.wolfram.com/HessianNormalForm.html
518 // the first three are the coordinates of the orthonormal vector
519 // the fourth coordinate is equal to the distance from the origin
521 for(Int_t i=0;i<3;i++){
524 plane[3] = ( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
526 // The center of the square with fiducial marks as corners
527 // as the middle point of one diagonal - md
528 // Used below to get the center - orig - of the surveyed box
530 Double_t orig[3], md[3];
531 for(Int_t i=0;i<3;i++){
532 md[i] = (ngA[i] + ngC[i]) * 0.5;
535 // The center of the box, gives the global translation
536 for(Int_t i=0;i<3;i++){
537 orig[i] = md[i] - plane[i]*fgkYFM;
540 // get local directions needed to write the global rotation matrix
541 // for the surveyed volume by normalising vectors ab and bc
542 Double_t sx = TMath::Sqrt(ab[0]*ab[0] + ab[1]*ab[1] + ab[2]*ab[2]);
544 for(Int_t i=0;i<3;i++){
548 Double_t sy = TMath::Sqrt(bc[0]*bc[0] + bc[1]*bc[1] + bc[2]*bc[2]);
550 for(Int_t i=0;i<3;i++){
554 Double_t rot[9] = {ab[0],plane[0],bc[0],ab[1],plane[1],-bc[1],ab[2],plane[2],-bc[2]}; // the rotation matrix
556 // the Aligned matrix for the current TOF SMS in the Global RS, as derived from Survey:
558 ng.SetTranslation(orig);
560 printf("\n\n**** The Misaligned Matrix in GRS, as from Survey data ***\n");
563 // Calculate the delta transformation wrt Ideal geometry
564 // (Should be gdelta.rot ==I and gdelta.tr=0 if no misalignment is applied.)
565 printf("\n\n**** The ideal matrix ***\n");
566 fTOFMatrixId[iSM]->Print();
567 TGeoHMatrix gdelta =fTOFMatrixId[iSM]->Inverse();
568 printf("\n\n**** The inverse of the ideal matrix ***\n");
570 gdelta.MultiplyLeft(&ng);
571 printf("\n\n**** The Delta Matrix in GRS, as from Survey data ***\n");
574 // Now Write the Alignment Objects....
575 TString symname(Form("TOF/sm%02d",iSM));
576 AliAlignObjMatrix* o = new AliAlignObjMatrix(symname.Data(),dvoluid,gdelta,kTRUE);
577 fTOFAlignObjArray->Add(o);
579 // saving TOF AligObjs from survey on a file, for the moment..
580 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
581 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
582 TFile f("TOFAlignFromSurvey.root","RECREATE");
584 f.WriteObject(fTOFAlignObjArray,"TOFAlignObjs","kSingleKey");