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 1.19 2007/10/02 09:46:08 arcelli
19 add methods to retrieve real survey data, and make some analysis (by B. Guerzoni)
21 Revision 1.17 2007/06/06 16:26:46 arcelli
22 remove fall-back call to local CDB storage
24 Revision 1.16 2007/05/15 16:25:44 cvetan
25 Moving the alignment-related static methods from AliAlignObj to the new geometry steering class AliGeomManager (macro from Raffaele)
27 Revision 1.15 2007/05/03 09:25:10 decaro
28 Coding convention: RN13 violation -> suppression
30 Revision 1.14 2007/04/18 14:49:54 arcelli
31 Some code cleanup, added more debug info
33 Revision 1.13 2007/04/17 16:38:36 arcelli
34 Include Methods to derive TOF AlignObjs from Survey Data
36 Revision 1.12 2007/02/28 18:09:23 arcelli
37 Add protection against failed retrieval of the CDB cal object
39 Revision 1.11 2006/09/19 14:31:26 cvetan
40 Bugfixes and clean-up of alignment object classes. Introduction of so called symbolic names used to identify the alignable volumes (Raffaele and Cvetan)
42 Revision 1.10 2006/08/22 13:26:05 arcelli
43 removal of effective c++ warnings (C.Zampolli)
45 Revision 1.9 2006/08/10 14:46:54 decaro
46 TOF raw data format: updated version
48 Revision 1.8 2006/05/04 19:41:42 hristov
49 Possibility for partial TOF geometry (S.Arcelli)
51 Revision 1.7 2006/04/27 13:13:29 hristov
52 Moving the destructor to the implementation file
54 Revision 1.6 2006/04/20 22:30:49 hristov
55 Coding conventions (Annalisa)
57 Revision 1.5 2006/04/16 22:29:05 hristov
58 Coding conventions (Annalisa)
60 Revision 1.4 2006/04/05 08:35:38 hristov
61 Coding conventions (S.Arcelli, C.Zampolli)
63 Revision 1.3 2006/03/31 13:49:07 arcelli
64 Removing some junk printout
66 Revision 1.2 2006/03/31 11:26:30 arcelli
67 changing CDB Ids according to standard convention
69 Revision 1.1 2006/03/28 14:54:48 arcelli
70 class for TOF alignment
72 author: Silvia Arcelli, arcelli@bo.infn.it
75 /////////////////////////////////////////////////////////
77 // Class for alignment procedure //
81 /////////////////////////////////////////////////////////
85 #include "TGeoMatrix.h"
89 #include "TGeoManager.h"
90 #include "TGeoVolume.h"
93 #include "TGeoPhysicalNode.h"
95 #include "TObjString.h"
98 //#include "AliAlignObj.h"
99 #include "AliAlignObjParams.h"
100 #include "AliAlignObjMatrix.h"
101 #include "AliCDBManager.h"
102 #include "AliCDBMetaData.h"
103 #include "AliCDBId.h"
104 #include "AliCDBEntry.h"
105 #include "AliTOFAlignment.h"
106 #include "AliSurveyObj.h"
107 #include "AliSurveyPoint.h"
109 ClassImp(AliTOFAlignment)
111 const Double_t AliTOFAlignment::fgkRorigTOF = 384.5; // Mean Radius of the TOF ext. volume, cm
112 const Double_t AliTOFAlignment::fgkX1BTOF = 124.5; //x1 size of BTOF
113 const Double_t AliTOFAlignment::fgkX2BTOF = 134.7262; //x2 size of BTOF
114 const Double_t AliTOFAlignment::fgkYBTOF = 747.2; //y size of BTOF
115 const Double_t AliTOFAlignment::fgkZBTOF = 29.0; //z size of BTOF
116 const Double_t AliTOFAlignment::fgkXFM = 38.0; //x pos of FM in BTOF, cm
117 const Double_t AliTOFAlignment::fgkYFM = 457.3; //y pos of FM in BTOF, cm
118 const Double_t AliTOFAlignment::fgkZFM = 11.2; //z pos of FM in BTOF, cm
120 //_____________________________________________________________________________
121 AliTOFAlignment::AliTOFAlignment():
122 TTask("AliTOFAlignment",""),
125 fTOFAlignObjArray(0x0)
127 //AliTOFalignment main Ctor
128 for(Int_t i=0; i<18;i++)
129 for(Int_t j=0; j<5; j++)
131 for(Int_t i=0; i<72; i++)
132 for (Int_t j=0; j<6; j++)
135 //_____________________________________________________________________________
136 AliTOFAlignment::AliTOFAlignment(const AliTOFAlignment &t):
138 fNTOFAlignObj(t.fNTOFAlignObj),
140 fTOFAlignObjArray(t.fTOFAlignObjArray)
142 //AliTOFAlignment copy Ctor
144 //AliTOFalignment main Ctor
145 for(Int_t i=0; i<18;i++)
146 for(Int_t j=0; j<5; j++)
147 fNFMforSM[i][j]=t.fNFMforSM[i][j];
148 for(Int_t i=0; i<72; i++)
149 for (Int_t j=0; j<6; j++)
150 fCombFMData[i][j]=t.fCombFMData[i][j];
152 //_____________________________________________________________________________
153 AliTOFAlignment& AliTOFAlignment::operator=(const AliTOFAlignment &t){
154 //AliTOFAlignment assignment operator
160 fNTOFAlignObj=t.fNTOFAlignObj;
162 fTOFAlignObjArray=t.fTOFAlignObjArray;
166 //_____________________________________________________________________________
167 AliTOFAlignment::~AliTOFAlignment() {
168 delete fTOFAlignObjArray;
172 //_____________________________________________________________________________
173 void AliTOFAlignment::Smear( Float_t *tr, Float_t *rot)
175 //Introduce Random Offset/Tilts
176 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
177 Float_t dx, dy, dz; // shifts
178 Float_t dpsi, dtheta, dphi; // angular displacements
179 TRandom *rnd = new TRandom(1567);
182 AliGeomManager::ELayerID iLayer = AliGeomManager::kInvalidLayer;
183 UShort_t iIndex=0; //dummy volume index
184 // AliGeomManager::ELayerID iLayer = AliGeomManager::kTOF;
185 // Int_t iIndex=1; //dummy volume index
186 UShort_t dvoluid = AliGeomManager::LayerToVolUID(iLayer,iIndex); //dummy volume identity
188 for (i = 0; i<nSMTOF ; i++) {
190 sprintf(path,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",i,i);
192 dx = (rnd->Gaus(0.,1.))*tr[0];
193 dy = (rnd->Gaus(0.,1.))*tr[1];
194 dz = (rnd->Gaus(0.,1.))*tr[2];
198 AliAlignObjParams *o =new AliAlignObjParams(path, dvoluid, dx, dy, dz, dpsi, dtheta, dphi, kTRUE);
199 fTOFAlignObjArray->Add(o);
202 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
203 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
207 //_____________________________________________________________________________
208 void AliTOFAlignment::Align( Float_t *tr, Float_t *rot)
210 //Introduce Offset/Tilts
212 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
213 Float_t dx, dy, dz; // shifts
214 Float_t dpsi, dtheta, dphi; // angular displacements
218 AliGeomManager::ELayerID iLayer = AliGeomManager::kInvalidLayer;
219 UShort_t iIndex=0; //dummy volume index
220 UShort_t dvoluid = AliGeomManager::LayerToVolUID(iLayer,iIndex); //dummy volume identity
222 for (i = 0; i<nSMTOF ; i++) {
225 sprintf(path,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",i,i);
233 AliAlignObjParams *o =new AliAlignObjParams(path, dvoluid, dx, dy, dz, dpsi, dtheta, dphi, kTRUE);
234 fTOFAlignObjArray->Add(o);
236 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
237 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
239 //_____________________________________________________________________________
240 void AliTOFAlignment::WriteParOnCDB(const Char_t *sel, Int_t minrun, Int_t maxrun)
242 //Write Align Par on CDB
243 AliCDBManager *man = AliCDBManager::Instance();
244 const Char_t *sel1 = "AlignPar" ;
246 sprintf(out,"%s/%s",sel,sel1);
247 AliCDBId idTOFAlign(out,minrun,maxrun);
248 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
249 mdTOFAlign->SetResponsible("TOF");
250 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
251 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
253 //_____________________________________________________________________________
254 void AliTOFAlignment::ReadParFromCDB(const Char_t *sel, Int_t nrun)
256 //Read Align Par from CDB
257 AliCDBManager *man = AliCDBManager::Instance();
258 const Char_t *sel1 = "AlignPar" ;
260 sprintf(out,"%s/%s",sel,sel1);
261 AliCDBEntry *entry = man->Get(out,nrun);
263 AliError(Form("Failed to get entry: %s",out));
266 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
267 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
268 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
271 //_____________________________________________________________________________
272 void AliTOFAlignment::WriteSimParOnCDB(const Char_t *sel, Int_t minrun, Int_t maxrun)
274 //Write Sim Align Par on CDB
275 AliCDBManager *man = AliCDBManager::Instance();
276 const Char_t *sel1 = "AlignSimPar" ;
278 sprintf(out,"%s/%s",sel,sel1);
279 AliCDBId idTOFAlign(out,minrun,maxrun);
280 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
281 mdTOFAlign->SetResponsible("TOF");
282 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
283 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
285 //_____________________________________________________________________________
286 void AliTOFAlignment::ReadSimParFromCDB(const Char_t *sel, Int_t nrun){
287 //Read Sim Align Par from CDB
288 AliCDBManager *man = AliCDBManager::Instance();
289 const Char_t *sel1 = "AlignSimPar" ;
291 sprintf(out,"%s/%s",sel,sel1);
292 AliCDBEntry *entry = man->Get(out,nrun);
293 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
294 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
295 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
298 //_____________________________________________________________________________
299 void AliTOFAlignment::WriteOnCDBforDC()
301 //Write Align Par on CDB for DC06
302 AliCDBManager *man = AliCDBManager::Instance();
303 AliCDBId idTOFAlign("TOF/Align/Data",0,0);
304 AliCDBMetaData *mdTOFAlign = new AliCDBMetaData();
305 mdTOFAlign->SetComment("Alignment objects for ideal geometry, i.e. applying them to TGeo has to leave geometry unchanged");
306 mdTOFAlign->SetResponsible("TOF");
307 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
308 man->Put(fTOFAlignObjArray,idTOFAlign,mdTOFAlign);
310 //_____________________________________________________________________________
311 void AliTOFAlignment::ReadFromCDBforDC()
313 //Read Sim Align Par from CDB for DC06
314 AliCDBManager *man = AliCDBManager::Instance();
315 AliCDBEntry *entry = man->Get("TOF/Align/Data",0);
316 fTOFAlignObjArray=(TObjArray*)entry->GetObject();
317 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
318 AliInfo(Form("Number of Alignable Volumes from CDB: %d",fNTOFAlignObj));
322 //_____________________________________________________________________________
323 void AliTOFAlignment::BuildGeomForSurvey()
326 //Generates the ideal TOF structure with four Fiducial Marks in each
327 //supermodule (two on each z side) in their expected position.
330 fTOFmgr = new TGeoManager("Geom","survey to alignment for TOF");
331 TGeoMedium *medium = 0;
332 TGeoVolume *top = fTOFmgr->MakeBox("TOP",medium,1000,1000,1000);
333 fTOFmgr->SetTopVolume(top);
334 // make shape components:
335 // This is the BTOF containing the FTOA
336 TGeoTrd1 *strd1 = new TGeoTrd1(fgkX1BTOF*0.5,fgkX2BTOF*0.5, fgkYBTOF*0.5,fgkZBTOF*0.5);
337 TGeoVolume* trd1[18];
339 // Now four fiducial marks on SM, expressed in local coordinates
340 // They are positioned at x=+/- 38 cm, y=+/- 457.3 cm, z=11.2 cm
342 TGeoBBox *fmbox = new TGeoBBox(1,1,1);
343 TGeoVolume* fm = new TGeoVolume("FM",fmbox);
347 TGeoTranslation* mAtr = new TGeoTranslation("mAtr",-fgkXFM, -fgkYFM ,fgkZFM);
348 TGeoTranslation* mBtr = new TGeoTranslation("mBtr",fgkXFM, -fgkYFM ,fgkZFM );
349 TGeoTranslation* mCtr = new TGeoTranslation("mCtr",fgkXFM, fgkYFM ,fgkZFM );
350 TGeoTranslation* mDtr = new TGeoTranslation("mDtr",-fgkXFM, fgkYFM ,fgkZFM );
352 // position all this stuff in the global ALICE frame
358 Float_t smR = fgkRorigTOF;
359 for (Int_t iSM = 0; iSM < 18; iSM++) {
360 Int_t mod = iSM + 13;
361 if (mod > 17) mod -= 18;
362 sprintf(name, "BTOF%d",mod);
363 trd1[iSM] = new TGeoVolume(name,strd1);
364 Float_t phi = iSM * 20.;
365 Float_t phi2 = 270 + phi;
366 if (phi2 >= 360.) phi2 -= 360.;
367 smX = TMath::Sin(phi*TMath::Pi()/180.)*smR;
368 smY = -TMath::Cos(phi*TMath::Pi()/180.)*smR;
370 TGeoRotation* bTOFRot = new TGeoRotation("bTOFRot",phi,90,0.);
371 TGeoCombiTrans trans = *(new TGeoCombiTrans(smX,smY,smZ, bTOFRot));
372 TGeoMatrix* id = new TGeoHMatrix();
373 TGeoHMatrix transMat = *id * trans;
374 TGeoHMatrix *smTrans = new TGeoHMatrix(transMat);
376 trd1[iSM]->AddNode(fm,1,mAtr); //place FM in BTOF
377 trd1[iSM]->AddNode(fm,2,mBtr);
378 trd1[iSM]->AddNode(fm,3,mCtr);
379 trd1[iSM]->AddNode(fm,4,mDtr);
380 top->AddNode(trd1[iSM],1,smTrans); //place BTOF_iSM in ALICE
381 trd1[iSM]->SetVisDaughters();
382 trd1[iSM]->SetLineColor(iSM); //black
386 fTOFmgr->CloseGeometry();
387 fTOFmgr->GetTopVolume()->Draw();
388 fTOFmgr->SetVisOption(0);
389 fTOFmgr->SetVisLevel(6);
391 // Now Store the "Ideal" Global Matrices (local to global) for later use
393 for (Int_t iSM = 0; iSM < 18; iSM++) {
395 sprintf(name, "TOP_1/BTOF%d_1", iSM);
396 printf("\n\n***************** TOF SuperModule: %s ****************** \n",name);
397 TGeoPhysicalNode* pn3 = fTOFmgr->MakePhysicalNode(name);
398 fTOFMatrixId[iSM] = pn3->GetMatrix(); //save "ideal" global matrix
399 printf("\n\n*************** The Ideal Matrix in GRS *****************\n");
400 fTOFMatrixId[iSM]->Print();
405 //_____________________________________________________________________________
406 void AliTOFAlignment::InsertMisAlignment(Float_t *mis)
408 // Now Apply the Displacements and store the misaligned FM positions...
412 Double_t lA[3]={-fgkXFM, -fgkYFM ,fgkZFM};
413 Double_t lB[3]={fgkXFM, -fgkYFM ,fgkZFM};
414 Double_t lC[3]={fgkXFM, fgkYFM ,fgkZFM};
415 Double_t lD[3]={-fgkXFM, fgkYFM ,fgkZFM};
417 for(Int_t iSM=0;iSM<18;iSM++){
419 sprintf(name, "TOP_1/BTOF%d_1", iSM);
421 printf("\n\n******Misaligning TOF SuperModule ************** %s \n",name);
423 // ************* get ideal global matrix *******************
424 TGeoHMatrix g3 = *fTOFmgr->GetCurrentMatrix();
425 AliInfo(Form("This is the ideal global trasformation of SM %i",iSM));
426 g3.Print(); // g3 is the local(BTOF) to global (ALICE) matrix and is the same of fTOFMatrixId
427 TGeoNode* n3 = fTOFmgr->GetCurrentNode();
428 TGeoMatrix* l3 = n3->GetMatrix();
430 Double_t gA[3], gB[3], gC[3], gD[3]; // ideal global FM point coord.
431 g3.LocalToMaster(lA,gA);
432 g3.LocalToMaster(lB,gB);
433 g3.LocalToMaster(lC,gC);
434 g3.LocalToMaster(lD,gD);
436 // We apply a delta transformation to the surveyed vol to represent
437 // its real position, given below by ng3 nl3, which differs from its
438 // ideal position saved above in g3 and l3
440 //we have to express the displacements as regards the old local RS (non misaligned BTOF)
441 Double_t dx = mis[0]; // shift along x
442 Double_t dy = mis[1]; // shift along y
443 Double_t dz = mis[2]; // shift along z
444 Double_t dphi = mis[3]; // rot around z
445 Double_t dtheta = mis[4]; // rot around x'
446 Double_t dpsi = mis[5]; // rot around z''
448 TGeoRotation* rrot = new TGeoRotation("rot",dphi,dtheta,dpsi);
449 TGeoCombiTrans localdelta = *(new TGeoCombiTrans(dx,dy,dz, rrot));
450 AliInfo(Form("This is the local delta trasformation for SM %i \n",iSM));
452 TGeoHMatrix nlocal = *l3 * localdelta;
453 TGeoHMatrix* nl3 = new TGeoHMatrix(nlocal); // new matrix, representing real position (from new local mis RS to the global one)
455 TGeoPhysicalNode* pn3 = fTOFmgr->MakePhysicalNode(name);
459 TGeoHMatrix* ng3 = pn3->GetMatrix(); //"real" global matrix, what survey sees
460 printf("\n\n************* The Misaligned Matrix in GRS **************\n");
462 Double_t ngA[3], ngB[3], ngC[3], ngD[3];// real FM point coord., global RS
463 ng3->LocalToMaster(lA,ngA);
464 ng3->LocalToMaster(lB,ngB);
465 ng3->LocalToMaster(lC,ngC);
466 ng3->LocalToMaster(lD,ngD);
468 for(Int_t coord=0;coord<3;coord++){
469 fCombFMData[iSM*4][2*coord]=ngA[coord];
470 fCombFMData[iSM*4][2*coord+1]=1;
471 fCombFMData[iSM*4+1][2*coord]=ngB[coord];
472 fCombFMData[iSM*4+1][2*coord+1]=1;
473 fCombFMData[iSM*4+2][2*coord]=ngC[coord];
474 fCombFMData[iSM*4+2][2*coord+1]=1;
475 fCombFMData[iSM*4+3][2*coord]=ngD[coord];
476 fCombFMData[iSM*4+3][2*coord+1]=1;
482 //____________________________________________________________________________
483 void AliTOFAlignment::WriteCombData(const Char_t *nomefile, Int_t option)
485 // 1 for simulated data; 0 for data from survey file
486 // write combined data on a file
490 /* Open file in text mode: */
491 if( (data = fopen( nomefile, "w+t" )) != NULL ){
493 fprintf( data, "simulated data\n" );} else {
494 fprintf( data, "survey data\n" );}
496 fprintf( data, "data from InsertMisAlignmentBTOF method\n");}
497 else {fprintf( data, "real survey data from text file (coordinate in global RS)\n");}
498 fprintf( data, "Point Name,XPH,YPH,ZPH,PrecisionX(mm),PrecisionY(mm),PrecisionZ(mm)\n");
499 fprintf( data, "> Data:\n");
500 for(Int_t i=0;i<72;i++){
501 if (fCombFMData[i][0]!=0){
502 fprintf( data, "SM%02iFM%i %f %f %f M Y %f %f %f\n", (i-i%4)/4, i%4, fCombFMData[i][0],fCombFMData[i][2],fCombFMData[i][4],fCombFMData[i][1]*10,fCombFMData[i][3]*10,fCombFMData[i][5]*10);
508 printf( "Problem opening the file\n" );
514 //____________________________________________________________________________
515 void AliTOFAlignment::WriteSimSurveyData(const Char_t *nomefile)
517 // write sim data in standard format
522 /* Open file in text mode: */
523 if( (data = fopen( nomefile, "w+t" )) != NULL )
525 fprintf( data, "> Title:\n" );
526 fprintf( data, "simulated data\n" );
527 fprintf( data, "> Date:\n" );
528 fprintf( data, "24.09.2007\n" );
529 fprintf( data, "> Subdetector:\n" );
530 fprintf( data, "TOF\n" );
531 fprintf( data, "> Report URL:\n" );
532 fprintf( data, "https://edms.cern.ch/document/835615\n" );
533 fprintf( data, "> Version:\n" );
534 fprintf( data, "1\n");
535 fprintf( data, "> General Observations:\n");
536 fprintf( data, "data from InsertMisAlignmentBTOF method\n");
537 fprintf( data, "> Coordinate System:\n");
538 fprintf( data, "\\ALICEPH\n");
539 fprintf( data, "> Units:\n");
540 fprintf( data, "cm\n");
541 fprintf( data, "> Nr Columns:\n");
542 fprintf( data, "9\n");
543 fprintf( data, "> Column Names:\n");
544 fprintf( data, "Point Name,XPH,YPH,ZPH,Point Type,Target Used,PrecisionX(mm),PrecisionY(mm),PrecisionZ(mm)\n");
545 fprintf( data, "> Data:\n");
546 for(Int_t i=0;i<72;i++)
547 if (fCombFMData[i][0]!=0)
548 fprintf( data, "SM%02iFM%i %f %f %f M Y %f %f %f\n", (i-i%4)/4, i%4, fCombFMData[i][0],fCombFMData[i][2],fCombFMData[i][4],fCombFMData[i][1],fCombFMData[i][3],fCombFMData[i][5]);
553 printf( "Problem opening the file\n" );
556 //____________________________________________________________________________
557 void AliTOFAlignment::MakeDefData(const Int_t nf,TString namefiles[])
559 //this method combines survey data from different files (namefiles[])
563 Float_t data[72][6][100];
564 for (Int_t i=0;i<72;i++)
565 for (Int_t j=0; j<6; j++)
566 for(Int_t k=0; k<100; k++)
570 Long64_t totdata[72]={0};
572 for (Int_t ii=0;ii<nf; ii++)
574 AliSurveyObj *so = new AliSurveyObj();
575 const Char_t *nome=namefiles[ii];
576 so->FillFromLocalFile(nome);
577 TObjArray *points = so->GetData();
578 Int_t nSurveyPoint=points->GetEntries();
579 for(Int_t jj=0;jj<nSurveyPoint;jj++){
580 const char* pointName= ((AliSurveyPoint *) points->At(jj))->GetPointName().Data();
581 nfm=atoi(&pointName[6]);
582 nsm=atoi(&pointName[2]);
583 data[nsm*4+nfm][0][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetX();
584 data[nsm*4+nfm][2][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetY();
585 data[nsm*4+nfm][4][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetZ();
586 data[nsm*4+nfm][1][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetPrecisionX();
587 data[nsm*4+nfm][3][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetPrecisionY();
588 data[nsm*4+nfm][5][totdata[nsm*4+nfm]]=((AliSurveyPoint *) points->At(jj))->GetPrecisionZ();
589 totdata[nsm*4+nfm]=totdata[nsm*4+nfm]+1;
595 for(Int_t i=0; i<72 ;i++){
596 Float_t numx=0, numy=0,numz=0, comodox=0, comodoy=0, comodoz=0,denx=0, deny=0, denz=0;
598 for(Int_t j=0; j<totdata[i]; j++){
599 comodox=1/(data[i][1][j]/10*data[i][1][j]/10);//precision in mm, position in cm
600 numx=numx+data[i][0][j]*comodox;
602 comodoy=1/(data[i][3][j]/10*data[i][3][j]/10);
603 numy=numy+data[i][2][j]*comodoy;
605 comodoz=1/(data[i][5][j]/10*data[i][5][j]/10);
606 numz=numz+data[i][4][j]*comodoz;
609 fCombFMData[i][1]=TMath::Sqrt(1/denx); //error for x position
610 fCombFMData[i][3]=TMath::Sqrt(1/deny); //error for y position
611 fCombFMData[i][5]=TMath::Sqrt(1/denz); //error for z position
612 fCombFMData[i][0]=numx/denx; //combined survey data for x position of FM
613 fCombFMData[i][2]=numy/deny; //combined survey data for y position of FM
614 fCombFMData[i][4]=numz/denz; //combined survey data for z position of FM
618 for(Int_t i=0;i<72;i++)
619 if (fCombFMData[i][0]!=0){
620 fNFMforSM[(i-i%4)/4][i%4]=1;
621 fNFMforSM[(i-i%4)/4][4]=fNFMforSM[(i-i%4)/4][4]+1;
625 //_____________________________________________________________________________
626 void AliTOFAlignment::ReadSurveyDataAndAlign(){
628 // read the survey data and, if we know the positions of at least 3 FM
629 //for a SM, call the right Alignement procedure
631 fTOFAlignObjArray = new TObjArray(kMaxAlignObj);
633 Float_t deltaFM0=0, deltaFM1=0, deltaFM2=0, deltaFM3=0;
635 for(Int_t i=0; i<18; i++){
636 switch(fNFMforSM[i][4]){
638 printf("we don't know the position of any FM of SM %i\n",i);
641 printf("we know the position of only one FM for SM %i\n",i);
645 printf("we know the position of only 2 FM for SM %i\n",i);
649 if (fNFMforSM[i][0]==1 && fNFMforSM[i][1]==1 && fNFMforSM[i][2]==1){
650 printf("we know the position of FM A B C for SM %i\n",i);
651 AliTOFAlignment::AlignFromSurveyABC(i);};
654 if (fNFMforSM[i][0]==1 && fNFMforSM[i][1]==1 && fNFMforSM[i][3]==1){
655 printf("we know the position of FM A B D for SM %i\n",i);
656 AliTOFAlignment::AlignFromSurveyABD(i);};
659 if (fNFMforSM[i][0]==1 && fNFMforSM[i][2]==1 && fNFMforSM[i][3]==1){
660 printf("we know the position of FM A C D for SM %i\n",i);
661 AliTOFAlignment::AlignFromSurveyACD(i);};
664 if (fNFMforSM[i][1]==1 && fNFMforSM[i][2]==1 && fNFMforSM[i][3]==1){
665 printf("we know the position of FM B C D for SM %i\n",i);
666 AliTOFAlignment::AlignFromSurveyBCD(i);};
671 printf("we know the position of all the 4 FM for SM %i\n",i);
672 //check the precision of the measurement
674 deltaFM0=fCombFMData[i*4][1]/TMath::Abs(fCombFMData[i*4][0])+fCombFMData[i*4][3]/TMath::Abs(fCombFMData[i*4][2])+fCombFMData[i*4][5]/TMath::Abs(fCombFMData[i*4][4]);
675 deltaFM1=fCombFMData[i*4+1][1]/TMath::Abs(fCombFMData[i*4+1][0])+fCombFMData[i*4+1][3]/TMath::Abs(fCombFMData[i*4+1][2])+fCombFMData[i*4+1][5]/TMath::Abs(fCombFMData[i*4+1][4]);
676 deltaFM2=fCombFMData[i*4+2][1]/TMath::Abs(fCombFMData[i*4+2][0])+fCombFMData[i*4+2][3]/TMath::Abs(fCombFMData[i*4+2][2])+fCombFMData[i*4+2][5]/TMath::Abs(fCombFMData[i*4+2][4]);
677 deltaFM3=fCombFMData[i*4+3][1]/TMath::Abs(fCombFMData[i*4+3][0])+fCombFMData[i*4+3][3]/TMath::Abs(fCombFMData[i*4+3][2])+fCombFMData[i*4+3][5]/TMath::Abs(fCombFMData[i*4+3][4]);
679 //to AlignFromSurvey we use the 3 FM whose positions are known with greatest precision
680 if(deltaFM0>=deltaFM1 && deltaFM0>=deltaFM2 && deltaFM0>=deltaFM3){
681 printf("to Align we use FM B,C,D");
682 AliTOFAlignment::AlignFromSurveyBCD(i);} else
683 if(deltaFM1>=deltaFM0 && deltaFM1>=deltaFM2 && deltaFM1>=deltaFM3){
684 printf("to Align we use FM A,C,D");
685 AliTOFAlignment::AlignFromSurveyACD(i);} else
686 if(deltaFM2>=deltaFM0 && deltaFM2>=deltaFM1 && deltaFM2>=deltaFM3){
687 printf("to Align we use FM A,B,D");
688 AliTOFAlignment::AlignFromSurveyABD(i);} else{
689 printf("to Align we use FM A,B,C");
690 AliTOFAlignment::AlignFromSurveyABC(i);}
697 // saving TOF AligObjs from survey on a file, for the moment..
698 fNTOFAlignObj=fTOFAlignObjArray->GetEntries();
699 AliInfo(Form("Number of Alignable Volumes: %d",fNTOFAlignObj));
700 TFile f("TOFAlignFromSurvey.root","RECREATE");
702 f.WriteObject(fTOFAlignObjArray,"TOFAlignObjs","kSingleKey");
708 //_____________________________________________________________________________
709 void AliTOFAlignment::AlignFromSurveyABC(Int_t iSM)
712 //From Survey data, derive the needed transformations to get the
714 //Again, highly "inspired" to Raffaele's example...
717 Double_t ngA[3], ngB[3], ngC[3]; // real FM point coord., global RS
718 // Get the 'realistic' input from the Survey Matrix
719 for(Int_t coord=0;coord<3;coord++){
720 ngA[coord]= fCombFMData[iSM*4][coord*2];
721 ngB[coord]= fCombFMData[iSM*4+1][coord*2];
722 ngC[coord]= fCombFMData[iSM*4+2][coord*2];
725 printf("\n\n******Survey analysis for TOF SuperModule ************** %i \n",iSM);
727 // From the real fiducial marks coordinates derive back the
728 // new global position of the surveyed volume
729 //*** What follows is the actual survey-to-alignment procedure
731 Double_t ab[3], bc[3], n[3];
732 Double_t plane[4], s=1.;
734 // first vector on the plane of the fiducial marks
735 for(Int_t i=0;i<3;i++){
736 ab[i] = (ngB[i] - ngA[i]);
739 // second vector on the plane of the fiducial marks
740 for(Int_t i=0;i<3;i++){
741 bc[i] = (ngC[i] - ngB[i]);
744 // vector normal to the plane of the fiducial marks obtained
745 // as cross product of the two vectors on the plane d0^d1
746 n[0] = (ab[1] * bc[2] - ab[2] * bc[1]);
747 n[1] = (ab[2] * bc[0] - ab[0] * bc[2]);
748 n[2] = (ab[0] * bc[1] - ab[1] * bc[0]);
750 Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
752 s = Double_t(1.)/sizen ; //normalization factor
754 AliInfo("Problem in normalizing the vector");
757 // plane expressed in the hessian normal form, see:
758 // http://mathworld.wolfram.com/HessianNormalForm.html
759 // the first three are the coordinates of the orthonormal vector
760 // the fourth coordinate is equal to the distance from the origin
762 for(Int_t i=0;i<3;i++){
765 plane[3] = ( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
767 // The center of the square with fiducial marks as corners
768 // as the middle point of one diagonal - md
769 // Used below to get the center - orig - of the surveyed box
771 Double_t orig[3], md[3];
772 for(Int_t i=0;i<3;i++){
773 md[i] = (ngA[i] + ngC[i]) * 0.5;
776 // The center of the box, gives the global translation
777 for(Int_t i=0;i<3;i++){
778 orig[i] = md[i] - plane[i]*fgkZFM;
781 // get local directions needed to write the global rotation matrix
782 // for the surveyed volume by normalising vectors ab and bc
783 Double_t sx = TMath::Sqrt(ab[0]*ab[0] + ab[1]*ab[1] + ab[2]*ab[2]);
787 for(Int_t i=0;i<3;i++){
791 Double_t sy = TMath::Sqrt(bc[0]*bc[0] + bc[1]*bc[1] + bc[2]*bc[2]);
793 for(Int_t i=0;i<3;i++){
797 Double_t rot[9] = {ab[0],bc[0],plane[0],ab[1],bc[1],plane[1],ab[2],bc[2],plane[2]}; // the rotation matrix
798 // the Aligned matrix for the current TOF SM in the Global RS, as derived from Survey
800 ng.SetTranslation(orig);
802 printf("\n\n**** The Misaligned Matrix in GRS, as from Survey data ***\n");
805 // Calculate the delta transformation wrt Ideal geometry
806 // (Should be gdelta.rot ==I and gdelta.tr=0 if no misalignment is applied.)
808 printf("\n\n**** The ideal matrix ***\n");
809 fTOFMatrixId[iSM]->Print();
811 TGeoHMatrix gdelta =fTOFMatrixId[iSM]->Inverse();
812 printf("\n\n**** The inverse of the ideal matrix ***\n");
815 gdelta.MultiplyLeft(&ng);
816 printf("\n\n**** The Delta Matrix in GRS, as from Survey data ***\n");
817 gdelta.Print(); //this is the global delta trasformation
819 // Now Write the Alignment Objects....
820 Int_t index=0; //let all SM modules have index=0
821 AliGeomManager::ELayerID layer = AliGeomManager::kInvalidLayer;
822 UShort_t dvoluid = AliGeomManager::LayerToVolUID(layer,index); //dummy vol id
823 TString symname(Form("TOF/sm%02d",iSM));
824 AliAlignObjMatrix* o = new AliAlignObjMatrix(symname.Data(),dvoluid,gdelta,kTRUE);
825 fTOFAlignObjArray->Add(o);
830 //_____________________________________________________________________________
831 void AliTOFAlignment::AlignFromSurveyABD(Int_t iSM)
834 //From Survey data, derive the needed transformations to get the
836 //Again, highly "inspired" to Raffaele's example...
839 Double_t ngA[3], ngB[3], ngD[3];// real FM point coord., global RS
841 // Get the 'realistic' input from the Survey Matrix
842 for(Int_t coord=0;coord<3;coord++){
843 ngA[coord]= fCombFMData[iSM*4][coord*2];
844 ngB[coord]= fCombFMData[iSM*4+1][coord*2];
845 ngD[coord]= fCombFMData[iSM*4+3][coord*2];
848 printf("\n\n******Survey analysis for TOF SuperModule ************** %i \n",iSM);
850 // From the new fiducial marks coordinates derive back the
851 // new global position of the surveyed volume
852 //*** What follows is the actual survey-to-alignment procedure
854 Double_t ab[3], ad[3], n[3];
855 Double_t plane[4], s=1.;
857 // first vector on the plane of the fiducial marks
858 for(Int_t i=0;i<3;i++){
859 ab[i] = (ngB[i] - ngA[i]);
862 // second vector on the plane of the fiducial marks
863 for(Int_t i=0;i<3;i++){
864 ad[i] = (ngD[i] - ngA[i]);
867 // vector normal to the plane of the fiducial marks obtained
868 // as cross product of the two vectors on the plane d0^d1
869 n[0] = (ab[1] * ad[2] - ab[2] * ad[1]);
870 n[1] = (ab[2] * ad[0] - ab[0] * ad[2]);
871 n[2] = (ab[0] * ad[1] - ab[1] * ad[0]);
873 Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
875 s = Double_t(1.)/sizen ; //normalization factor
877 AliInfo("Problem in normalizing the vector");
880 // plane expressed in the hessian normal form, see:
881 // http://mathworld.wolfram.com/HessianNormalForm.html
882 // the first three are the coordinates of the orthonormal vector
883 // the fourth coordinate is equal to the distance from the origin
885 for(Int_t i=0;i<3;i++){
888 plane[3] = ( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
890 // The center of the square with fiducial marks as corners
891 // as the middle point of one diagonal - md
892 // Used below to get the center - orig - of the surveyed box
894 Double_t orig[3], md[3];
895 for(Int_t i=0;i<3;i++){
896 md[i] = (ngB[i] + ngD[i]) * 0.5;
899 // The center of the box, gives the global translation
900 for(Int_t i=0;i<3;i++){
901 orig[i] = md[i] - plane[i]*fgkZFM;
904 // get local directions needed to write the global rotation matrix
905 // for the surveyed volume by normalising vectors ab and bc
906 Double_t sx = TMath::Sqrt(ab[0]*ab[0] + ab[1]*ab[1] + ab[2]*ab[2]);
908 for(Int_t i=0;i<3;i++){
912 Double_t sy = TMath::Sqrt(ad[0]*ad[0] + ad[1]*ad[1] + ad[2]*ad[2]);
914 for(Int_t i=0;i<3;i++){
918 Double_t rot[9] = {ab[0],ad[0],plane[0],ab[1],ad[1],plane[1],ab[2],ad[2],plane[2]};
919 // the Aligned matrix for the current TOF SM in the Global RS, as derived from Survey:
921 ng.SetTranslation(orig);
923 printf("\n\n**** The Misaligned Matrix in GRS, as from Survey data ***\n");
926 // Calculate the delta transformation wrt Ideal geometry
927 // (Should be gdelta.rot ==I and gdelta.tr=0 if no misalignment is applied.)
929 printf("\n\n**** The ideal matrix ***\n");
930 fTOFMatrixId[iSM]->Print();
932 TGeoHMatrix gdelta =fTOFMatrixId[iSM]->Inverse();
933 printf("\n\n**** The inverse of the ideal matrix ***\n");
936 gdelta.MultiplyLeft(&ng);
937 printf("\n\n**** The Delta Matrix in GRS, as from Survey data ***\n");
938 gdelta.Print(); //global delta trasformation
940 // Now Write the Alignment Objects....
941 Int_t index=0; //let all SM modules have index=0
942 AliGeomManager::ELayerID layer = AliGeomManager::kInvalidLayer;
943 UShort_t dvoluid = AliGeomManager::LayerToVolUID(layer,index); //dummy vol id
944 TString symname(Form("TOF/sm%02d",iSM));
945 AliAlignObjMatrix* o = new AliAlignObjMatrix(symname.Data(),dvoluid,gdelta,kTRUE);
946 fTOFAlignObjArray->Add(o);
949 //_____________________________________________________________________________
950 void AliTOFAlignment::AlignFromSurveyACD(Int_t iSM)
952 //From Survey data, derive the needed transformations to get the
954 //Again, highly "inspired" to Raffaele's example...
958 Double_t ngA[3], ngC[3], ngD[3];// real FM point coord., global RS
960 // Get the 'realistic' input from the Survey Matrix
961 for(Int_t coord=0;coord<3;coord++){
962 ngA[coord]= fCombFMData[iSM*4][coord*2];
963 ngC[coord]= fCombFMData[iSM*4+2][coord*2];
964 ngD[coord]= fCombFMData[iSM*4+3][coord*2];
967 printf("\n\n******Survey analysis for TOF SuperModule ************** %i \n",iSM);
969 // From the new fiducial marks coordinates derive back the
970 // new global position of the surveyed volume
971 //*** What follows is the actual survey-to-alignment procedure
973 Double_t cd[3], ad[3], n[3];
974 Double_t plane[4], s=1.;
976 // first vector on the plane of the fiducial marks
977 for(Int_t i=0;i<3;i++){
978 cd[i] = (ngC[i] - ngD[i]);
981 // second vector on the plane of the fiducial marks
982 for(Int_t i=0;i<3;i++){
983 ad[i] = (ngD[i] - ngA[i]);
986 // vector normal to the plane of the fiducial marks obtained
987 // as cross product of the two vectors on the plane d0^d1
988 n[0] = (ad[1] * cd[2] - ad[2] * cd[1]);
989 n[1] = (ad[2] * cd[0] - ad[0] * cd[2]);
990 n[2] = (ad[0] * cd[1] - ad[1] * cd[0]);
992 Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
994 s = Double_t(1.)/sizen ; //normalization factor
996 AliInfo("Problem in normalizing the vector");
999 // plane expressed in the hessian normal form, see:
1000 // http://mathworld.wolfram.com/HessianNormalForm.html
1001 // the first three are the coordinates of the orthonormal vector
1002 // the fourth coordinate is equal to the distance from the origin
1004 for(Int_t i=0;i<3;i++){
1005 plane[i] = n[i] * s;
1007 plane[3] = ( plane[0] * ngA[0] + plane[1] * ngA[1] + plane[2] * ngA[2] );
1009 // The center of the square with fiducial marks as corners
1010 // as the middle point of one diagonal - md
1011 // Used below to get the center - orig - of the surveyed box
1013 Double_t orig[3], md[3];
1014 for(Int_t i=0;i<3;i++){
1015 md[i] = (ngA[i] + ngC[i]) * 0.5;
1018 // The center of the box, gives the global translation
1019 for(Int_t i=0;i<3;i++){
1020 orig[i] = md[i] + plane[i]*fgkZFM;
1023 // get local directions needed to write the global rotation matrix
1024 // for the surveyed volume by normalising vectors ab and bc
1025 Double_t sx = TMath::Sqrt(ad[0]*ad[0] + ad[1]*ad[1] + ad[2]*ad[2]);
1027 for(Int_t i=0;i<3;i++){
1031 Double_t sy = TMath::Sqrt(cd[0]*cd[0] + cd[1]*cd[1] + cd[2]*cd[2]);
1033 for(Int_t i=0;i<3;i++){
1037 Double_t rot[9] = {cd[0],ad[0],-plane[0],cd[1],ad[1],-plane[1],cd[2],ad[2],-plane[2]};
1038 // the Aligned matrix for the current TOF SM in the Global RS, as derived from Survey:
1040 ng.SetTranslation(orig);
1041 ng.SetRotation(rot);
1042 printf("\n\n**** The Misaligned Matrix in GRS, as from Survey data ***\n");
1045 // Calculate the delta transformation wrt Ideal geometry
1046 // (Should be gdelta.rot ==I and gdelta.tr=0 if no misalignment is applied.)
1048 printf("\n\n**** The ideal matrix ***\n");
1049 fTOFMatrixId[iSM]->Print();
1051 TGeoHMatrix gdelta =fTOFMatrixId[iSM]->Inverse();
1052 printf("\n\n**** The inverse of the ideal matrix ***\n");
1055 gdelta.MultiplyLeft(&ng);
1056 printf("\n\n**** The Delta Matrix in GRS, as from Survey data ***\n");
1057 gdelta.Print(); //global delta trasformation
1059 // Now Write the Alignment Objects....
1060 Int_t index=0; //let all SM modules have index=0
1061 AliGeomManager::ELayerID layer = AliGeomManager::kInvalidLayer;
1062 UShort_t dvoluid = AliGeomManager::LayerToVolUID(layer,index); //dummy vol id
1063 TString symname(Form("TOF/sm%02d",iSM));
1064 AliAlignObjMatrix* o = new AliAlignObjMatrix(symname.Data(),dvoluid,gdelta,kTRUE);
1065 fTOFAlignObjArray->Add(o);
1068 //___________________________________________________________________________
1069 void AliTOFAlignment::AlignFromSurveyBCD(Int_t iSM)
1071 //From Survey data, derive the needed transformations to get the
1072 //Alignment Objects.
1073 //Again, highly "inspired" to Raffaele's example...
1076 Double_t ngB[3], ngC[3], ngD[3];// real FM point coord., global RS
1079 // Get the 'realistic' input from the Survey Matrix
1080 for(Int_t coord=0;coord<3;coord++){
1081 ngB[coord]= fCombFMData[iSM*4+1][coord*2];
1082 ngC[coord]= fCombFMData[iSM*4+2][coord*2];
1083 ngD[coord]= fCombFMData[iSM*4+3][coord*2];
1086 printf("\n\n******Survey analysis for TOF SuperModule ************** %i \n",iSM);
1088 // From the new fiducial marks coordinates derive back the
1089 // new global position of the surveyed volume
1090 //*** What follows is the actual survey-to-alignment procedure
1092 Double_t cd[3], bc[3], n[3];
1093 Double_t plane[4], s=1.;
1095 // first vector on the plane of the fiducial marks
1096 for(Int_t i=0;i<3;i++){
1097 cd[i] = (ngC[i] - ngD[i]);
1100 // second vector on the plane of the fiducial marks
1101 for(Int_t i=0;i<3;i++){
1102 bc[i] = (ngC[i] - ngB[i]);
1105 // vector normal to the plane of the fiducial marks obtained
1106 // as cross product of the two vectors on the plane d0^d1
1107 n[0] = (bc[1] * cd[2] - bc[2] * cd[1]);
1108 n[1] = (bc[2] * cd[0] - bc[0] * cd[2]);
1109 n[2] = (bc[0] * cd[1] - bc[1] * cd[0]);
1111 Double_t sizen = TMath::Sqrt( n[0]*n[0] + n[1]*n[1] + n[2]*n[2] );
1113 s = Double_t(1.)/sizen ; //normalization factor
1115 AliInfo("Problem in normalizing the vector");
1118 // plane expressed in the hessian normal form, see:
1119 // http://mathworld.wolfram.com/HessianNormalForm.html
1120 // the first three are the coordinates of the orthonormal vector
1121 // the fourth coordinate is equal to the distance from the origin
1123 for(Int_t i=0;i<3;i++){
1124 plane[i] = n[i] * s;
1126 plane[3] = ( plane[0] * ngB[0] + plane[1] * ngB[1] + plane[2] * ngB[2] );
1128 // The center of the square with fiducial marks as corners
1129 // as the middle point of one diagonal - md
1130 // Used below to get the center - orig - of the surveyed box
1132 Double_t orig[3], md[3];
1133 for(Int_t i=0;i<3;i++){
1134 md[i] = (ngB[i] + ngD[i]) * 0.5;
1137 // The center of the box, gives the global translation
1138 for(Int_t i=0;i<3;i++){
1139 orig[i] = md[i] + plane[i]*fgkZFM;
1142 // get local directions needed to write the global rotation matrix
1143 // for the surveyed volume by normalising vectors ab and bc
1144 Double_t sx = TMath::Sqrt(cd[0]*cd[0] + cd[1]*cd[1] + cd[2]*cd[2]);
1146 for(Int_t i=0;i<3;i++){
1150 Double_t sy = TMath::Sqrt(bc[0]*bc[0] + bc[1]*bc[1] + bc[2]*bc[2]);
1152 for(Int_t i=0;i<3;i++){
1156 Double_t rot[9] = {cd[0],bc[0],-plane[0],cd[1],bc[1],-plane[1],cd[2],bc[2],-plane[2]};
1157 // the Aligned matrix for the current TOF SM in the Global RS, as derived from Survey:
1159 ng.SetTranslation(orig);
1160 ng.SetRotation(rot);
1161 printf("\n\n**** The Misaligned Matrix in GRS, as from Survey data ***\n");
1164 // Calculate the delta transformation wrt Ideal geometry
1165 // (Should be gdelta.rot ==I and gdelta.tr=0 if no misalignment is applied.)
1167 printf("\n\n**** The ideal matrix ***\n");
1168 fTOFMatrixId[iSM]->Print();
1170 TGeoHMatrix gdelta =fTOFMatrixId[iSM]->Inverse();
1171 printf("\n\n**** The inverse of the ideal matrix ***\n");
1174 gdelta.MultiplyLeft(&ng);
1175 printf("\n\n**** The Delta Matrix in GRS, as from Survey data ***\n");
1176 gdelta.Print(); //global delta trasformation
1178 // Now Write the Alignment Objects....
1179 Int_t index=0; //let all SM modules have index=0
1180 AliGeomManager::ELayerID layer = AliGeomManager::kInvalidLayer;
1181 UShort_t dvoluid = AliGeomManager::LayerToVolUID(layer,index); //dummy vol id
1182 TString symname(Form("TOF/sm%02d",iSM));
1183 AliAlignObjMatrix* o = new AliAlignObjMatrix(symname.Data(),dvoluid,gdelta,kTRUE);
1184 fTOFAlignObjArray->Add(o);