Removal of the last gAlice deps. In case of raw-data reconstruction and missing gAlic...
[u/mrichter/AliRoot.git] / TRD / AliTRDgeometry.cxx
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f7336fa3 1/**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
3 * *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
6 * *
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 **************************************************************************/
15
afc51ac2 16/* $Id$ */
f7336fa3 17
18///////////////////////////////////////////////////////////////////////////////
19// //
20// TRD geometry class //
21// //
22///////////////////////////////////////////////////////////////////////////////
23
793ff80c 24
b4a9cd27 25#include <TGeoManager.h>
26#include <TGeoPhysicalNode.h>
27#include <TGeoMatrix.h>
28
2745a409 29#include "AliLog.h"
bdbb05bb 30#include "AliRunLoader.h"
b4a9cd27 31#include "AliAlignObj.h"
32#include "AliAlignObjAngles.h"
ecb36af7 33#include "AliRun.h"
030b4415 34
ecb36af7 35#include "AliTRD.h"
3551db50 36#include "AliTRDcalibDB.h"
37#include "AliTRDCommonParam.h"
2745a409 38#include "AliTRDgeometry.h"
39#include "AliTRDpadPlane.h"
ecb36af7 40
f7336fa3 41ClassImp(AliTRDgeometry)
42
793ff80c 43//_____________________________________________________________________________
44
45 //
46 // The geometry constants
47 //
7925de54 48 const Int_t AliTRDgeometry::fgkNsect = kNsect;
49 const Int_t AliTRDgeometry::fgkNplan = kNplan;
50 const Int_t AliTRDgeometry::fgkNcham = kNcham;
51 const Int_t AliTRDgeometry::fgkNdet = kNdet;
793ff80c 52
53 //
54 // Dimensions of the detector
55 //
0a770ac9 56
0a5f3331 57 // Parameter of the BTRD mother volumes
7925de54 58 const Float_t AliTRDgeometry::fgkSheight = 77.9;
59 const Float_t AliTRDgeometry::fgkSwidth1 = 94.881;
60 const Float_t AliTRDgeometry::fgkSwidth2 = 122.353;
61 const Float_t AliTRDgeometry::fgkSlength = 751.0;
793ff80c 62
73ae7b59 63 // The super module side plates
7925de54 64 const Float_t AliTRDgeometry::fgkSMpltT = 0.2;
73ae7b59 65
0a770ac9 66 // Height of different chamber parts
67 // Radiator
7925de54 68 const Float_t AliTRDgeometry::fgkCraH = 4.8;
0a770ac9 69 // Drift region
7925de54 70 const Float_t AliTRDgeometry::fgkCdrH = 3.0;
0a770ac9 71 // Amplification region
7925de54 72 const Float_t AliTRDgeometry::fgkCamH = 0.7;
0a770ac9 73 // Readout
7925de54 74 const Float_t AliTRDgeometry::fgkCroH = 2.316;
0a770ac9 75 // Total height
7925de54 76 const Float_t AliTRDgeometry::fgkCH = AliTRDgeometry::fgkCraH
77 + AliTRDgeometry::fgkCdrH
78 + AliTRDgeometry::fgkCamH
79 + AliTRDgeometry::fgkCroH;
0a770ac9 80
81 // Vertical spacing of the chambers
7925de54 82 const Float_t AliTRDgeometry::fgkVspace = 1.784;
0a770ac9 83 // Horizontal spacing of the chambers
7925de54 84 const Float_t AliTRDgeometry::fgkHspace = 2.0;
a797f961 85 // Radial distance of the first ROC to the outer plates of the SM
7925de54 86 const Float_t AliTRDgeometry::fgkVrocsm = 1.2;
a797f961 87
0a770ac9 88 // Thicknesses of different parts of the chamber frame
89 // Lower aluminum frame
7925de54 90 const Float_t AliTRDgeometry::fgkCalT = 0.4;
0a5f3331 91 // Lower Wacosit frame sides
7925de54 92 const Float_t AliTRDgeometry::fgkCclsT = 0.21;
0a5f3331 93 // Lower Wacosit frame front
7925de54 94 const Float_t AliTRDgeometry::fgkCclfT = 1.0;
0a5f3331 95 // Thickness of glue around radiator
7925de54 96 const Float_t AliTRDgeometry::fgkCglT = 0.25;
0a5f3331 97 // Upper Wacosit frame
7925de54 98 const Float_t AliTRDgeometry::fgkCcuT = 0.9;
0a5f3331 99 // Al frame of back panel
7925de54 100 const Float_t AliTRDgeometry::fgkCauT = 1.5;
0a5f3331 101 // Additional Al of the lower chamber frame
7925de54 102 const Float_t AliTRDgeometry::fgkCalW = 1.11;
0a770ac9 103
104 // Additional width of the readout chamber frames
7925de54 105 const Float_t AliTRDgeometry::fgkCroW = 0.9;
0a770ac9 106
107 // Difference of outer chamber width and pad plane width
7925de54 108 const Float_t AliTRDgeometry::fgkCpadW = 0.0;
109 const Float_t AliTRDgeometry::fgkRpadW = 1.0;
793ff80c 110
111 //
112 // Thickness of the the material layers
113 //
7925de54 114 const Float_t AliTRDgeometry::fgkMyThick = 0.005;
115 const Float_t AliTRDgeometry::fgkRaThick = 0.3233;
116 const Float_t AliTRDgeometry::fgkDrThick = AliTRDgeometry::fgkCdrH;
117 const Float_t AliTRDgeometry::fgkAmThick = AliTRDgeometry::fgkCamH;
118 const Float_t AliTRDgeometry::fgkXeThick = AliTRDgeometry::fgkDrThick
119 + AliTRDgeometry::fgkAmThick;
120 const Float_t AliTRDgeometry::fgkWrThick = 0.0002;
121 const Float_t AliTRDgeometry::fgkCuThick = 0.0072;
122 const Float_t AliTRDgeometry::fgkGlThick = 0.05;
123 const Float_t AliTRDgeometry::fgkSuThick = 0.0919;
124 const Float_t AliTRDgeometry::fgkRcThick = 0.0058;
125 const Float_t AliTRDgeometry::fgkRpThick = 0.0632;
126 const Float_t AliTRDgeometry::fgkRoThick = 0.0028;
793ff80c 127
128 //
129 // Position of the material layers
130 //
7925de54 131 const Float_t AliTRDgeometry::fgkRaZpos = 0.0;
132 const Float_t AliTRDgeometry::fgkDrZpos = 2.4;
133 const Float_t AliTRDgeometry::fgkAmZpos = 0.0;
134 const Float_t AliTRDgeometry::fgkWrZpos = 0.0;
135 const Float_t AliTRDgeometry::fgkCuZpos = -0.9995;
136 const Float_t AliTRDgeometry::fgkGlZpos = -0.5;
137 const Float_t AliTRDgeometry::fgkSuZpos = 0.0;
138 const Float_t AliTRDgeometry::fgkRcZpos = 1.04;
139 const Float_t AliTRDgeometry::fgkRpZpos = 1.0;
140 const Float_t AliTRDgeometry::fgkRoZpos = 1.05;
141
142 const Int_t AliTRDgeometry::fgkMCMmax = 16;
143 const Int_t AliTRDgeometry::fgkMCMrow = 4;
144 const Int_t AliTRDgeometry::fgkROBmaxC0 = 6;
145 const Int_t AliTRDgeometry::fgkROBmaxC1 = 8;
146 const Int_t AliTRDgeometry::fgkADCmax = 21;
147 const Int_t AliTRDgeometry::fgkTBmax = 60;
148 const Int_t AliTRDgeometry::fgkPadmax = 18;
149 const Int_t AliTRDgeometry::fgkColmax = 144;
150 const Int_t AliTRDgeometry::fgkRowmaxC0 = 12;
151 const Int_t AliTRDgeometry::fgkRowmaxC1 = 16;
0a5f3331 152
153 const Double_t AliTRDgeometry::fgkTime0Base = 300.65;
7925de54 154 const Float_t AliTRDgeometry::fgkTime0[6] = { fgkTime0Base + 0 * (Cheight() + Cspace())
155 , fgkTime0Base + 1 * (Cheight() + Cspace())
156 , fgkTime0Base + 2 * (Cheight() + Cspace())
157 , fgkTime0Base + 3 * (Cheight() + Cspace())
158 , fgkTime0Base + 4 * (Cheight() + Cspace())
159 , fgkTime0Base + 5 * (Cheight() + Cspace())};
793ff80c 160
f7336fa3 161//_____________________________________________________________________________
2745a409 162AliTRDgeometry::AliTRDgeometry()
163 :AliGeometry()
164 ,fMatrixArray(0)
165 ,fMatrixCorrectionArray(0)
166 ,fMatrixGeo(0)
167
f7336fa3 168{
169 //
170 // AliTRDgeometry default constructor
171 //
bd0f8685 172
2745a409 173 Init();
174
175}
176
177//_____________________________________________________________________________
178AliTRDgeometry::AliTRDgeometry(const AliTRDgeometry &g)
179 :AliGeometry(g)
030b4415 180 ,fMatrixArray(g.fMatrixArray)
181 ,fMatrixCorrectionArray(g.fMatrixCorrectionArray)
182 ,fMatrixGeo(g.fMatrixGeo)
2745a409 183{
184 //
185 // AliTRDgeometry copy constructor
186 //
bd0f8685 187
f7336fa3 188 Init();
bd0f8685 189
f7336fa3 190}
191
192//_____________________________________________________________________________
193AliTRDgeometry::~AliTRDgeometry()
194{
8230f242 195 //
196 // AliTRDgeometry destructor
197 //
bd0f8685 198
030b4415 199 if (fMatrixArray) {
200 delete fMatrixArray;
201 fMatrixArray = 0;
202 }
203
204 if (fMatrixCorrectionArray) {
205 delete fMatrixCorrectionArray;
206 fMatrixCorrectionArray = 0;
207 }
bd0f8685 208
f7336fa3 209}
210
2745a409 211//_____________________________________________________________________________
212AliTRDgeometry &AliTRDgeometry::operator=(const AliTRDgeometry &g)
213{
214 //
215 // Assignment operator
216 //
217
0a5f3331 218 if (this != &g) {
219 Init();
220 }
030b4415 221
2745a409 222 return *this;
223
224}
225
f7336fa3 226//_____________________________________________________________________________
227void AliTRDgeometry::Init()
228{
229 //
230 // Initializes the geometry parameter
231 //
f7336fa3 232
0a770ac9 233 Int_t icham;
234 Int_t iplan;
235 Int_t isect;
236
237 // The outer width of the chambers
287c5d50 238 fCwidth[0] = 90.4;
e0d47c25 239 fCwidth[1] = 94.8;
240 fCwidth[2] = 99.3;
241 fCwidth[3] = 103.7;
242 fCwidth[4] = 108.1;
243 fCwidth[5] = 112.6;
0a770ac9 244
245 // The outer lengths of the chambers
73ae7b59 246 // Includes the spacings between the chambers!
8737e16f 247 Float_t length[kNplan][kNcham] = { { 124.0, 124.0, 110.0, 124.0, 124.0 }
e0d47c25 248 , { 124.0, 124.0, 110.0, 124.0, 124.0 }
8737e16f 249 , { 131.0, 131.0, 110.0, 131.0, 131.0 }
250 , { 138.0, 138.0, 110.0, 138.0, 138.0 }
251 , { 145.0, 145.0, 110.0, 145.0, 145.0 }
e0d47c25 252 , { 147.0, 147.0, 110.0, 147.0, 147.0 } };
0a770ac9 253
254 for (icham = 0; icham < kNcham; icham++) {
255 for (iplan = 0; iplan < kNplan; iplan++) {
030b4415 256 fClength[iplan][icham] = length[iplan][icham];
0a770ac9 257 }
258 }
259
793ff80c 260 // The rotation matrix elements
030b4415 261 Float_t phi = 0.0;
793ff80c 262 for (isect = 0; isect < fgkNsect; isect++) {
439c63c8 263 phi = 2.0 * TMath::Pi() / (Float_t) fgkNsect * ((Float_t) isect + 0.5);
793ff80c 264 fRotA11[isect] = TMath::Cos(phi);
265 fRotA12[isect] = TMath::Sin(phi);
266 fRotA21[isect] = TMath::Sin(phi);
267 fRotA22[isect] = TMath::Cos(phi);
268 phi = -1.0 * phi;
269 fRotB11[isect] = TMath::Cos(phi);
270 fRotB12[isect] = TMath::Sin(phi);
271 fRotB21[isect] = TMath::Sin(phi);
272 fRotB22[isect] = TMath::Cos(phi);
273 }
bd0f8685 274
275 for (isect = 0; isect < fgkNsect; isect++) {
276 SetSMstatus(isect,1);
277 }
793ff80c 278
279}
280
f7336fa3 281//_____________________________________________________________________________
bd0f8685 282void AliTRDgeometry::CreateGeometry(Int_t *idtmed)
283{
284 //
285 // Create the TRD geometry without hole
286 //
287 //
288 // Names of the TRD volumina (xx = detector number):
289 //
290 // Volume (Air) wrapping the readout chamber components
291 // UTxx includes: UAxx, UDxx, UFxx, UUxx
0a5f3331 292 //
293 // Volume (Air) wrapping the services (fee + cooling)
bd0f8685 294 // UUxx the services volume has been reduced by 7.42 mm
295 // in order to allow shifts in radial direction
296 //
0a5f3331 297 // Lower part of the readout chambers (drift volume + radiator)
bd0f8685 298 //
0a5f3331 299 // UAxx Aluminum frames (Al)
300 // UBxx Wacosit frames (C)
301 // UXxx Glue around radiator (Epoxy)
302 // UCxx Inner volumes (Air)
303 // UZxx Additional aluminum ledges (Al)
bd0f8685 304 //
305 // Upper part of the readout chambers (readout plane + fee)
306 //
0a5f3331 307 // UDxx Wacosit frames of amp. region (C)
308 // UExx Inner volumes of the frame (Air)
309 // UFxx Aluminum frame of back panel (Al)
310 // UGxx Inner volumes of the back panel (Air)
bd0f8685 311 //
312 // Inner material layers
313 //
0a5f3331 314 // UHxx Radiator (Rohacell)
315 // UJxx Drift volume (Xe/CO2)
316 // UKxx Amplification volume (Xe/CO2)
317 // UWxx Wire plane (Cu)
318 // ULxx Pad plane (Cu)
319 // UYxx Glue layer (Epoxy)
320 // UMxx Support structure (Rohacell)
321 // UNxx ROB base material (C)
322 // UOxx ROB copper (Cu)
323 // UVxx ROB other materials (Cu)
bd0f8685 324 //
325
326 const Int_t kNparTrd = 4;
327 const Int_t kNparCha = 3;
328
030b4415 329 Float_t xpos;
330 Float_t ypos;
331 Float_t zpos;
bd0f8685 332
333 Float_t parTrd[kNparTrd];
334 Float_t parCha[kNparCha];
335
336 Char_t cTagV[6];
337 Char_t cTagM[5];
338
339 // The TRD mother volume for one sector (Air), full length in z-direction
340 // Provides material for side plates of super module
030b4415 341 parTrd[0] = fgkSwidth1/2.0;
342 parTrd[1] = fgkSwidth2/2.0;
0a5f3331 343 parTrd[2] = fgkSlength/2.0;
030b4415 344 parTrd[3] = fgkSheight/2.0;
bd0f8685 345 gMC->Gsvolu("UTR1","TRD1",idtmed[1302-1],parTrd,kNparTrd);
346
a797f961 347 // The outer aluminum plates of the super module (Al)
030b4415 348 parTrd[0] = fgkSwidth1/2.0;
349 parTrd[1] = fgkSwidth2/2.0;
0a5f3331 350 parTrd[2] = fgkSlength/2.0;
030b4415 351 parTrd[3] = fgkSheight/2.0;
bd0f8685 352 gMC->Gsvolu("UTS1","TRD1",idtmed[1301-1],parTrd,kNparTrd);
353
354 // The inner part of the TRD mother volume for one sector (Air),
355 // full length in z-direction
030b4415 356 parTrd[0] = fgkSwidth1/2.0 - fgkSMpltT;
357 parTrd[1] = fgkSwidth2/2.0 - fgkSMpltT;
0a5f3331 358 parTrd[2] = fgkSlength/2.0;
030b4415 359 parTrd[3] = fgkSheight/2.0 - fgkSMpltT;
bd0f8685 360 gMC->Gsvolu("UTI1","TRD1",idtmed[1302-1],parTrd,kNparTrd);
361
362 for (Int_t icham = 0; icham < kNcham; icham++) {
363 for (Int_t iplan = 0; iplan < kNplan; iplan++) {
364
365 Int_t iDet = GetDetectorSec(iplan,icham);
366
0a5f3331 367 // The lower part of the readout chambers (drift volume + radiator)
bd0f8685 368 // The aluminum frames
369 sprintf(cTagV,"UA%02d",iDet);
030b4415 370 parCha[0] = fCwidth[iplan]/2.0;
371 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0;
372 parCha[2] = fgkCraH/2.0 + fgkCdrH/2.0;
bd0f8685 373 fChamberUAboxd[iDet][0] = parCha[0];
374 fChamberUAboxd[iDet][1] = parCha[1];
375 fChamberUAboxd[iDet][2] = parCha[2];
376 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
0a5f3331 377 // The additional aluminum on the frames
378 // This part has not the correct postion but is just supposed to
379 // represent the missing material. The correct from of the L-shaped
380 // profile would not fit into the alignable volume.
381 sprintf(cTagV,"UZ%02d",iDet);
382 parCha[0] = fgkCroW/2.0;
383 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0;
384 parCha[2] = fgkCalW/2.0;
385 fChamberUAboxd[iDet][0] = fChamberUAboxd[iDet][0] + fgkCroW;
386 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
387 // The Wacosit frames
bd0f8685 388 sprintf(cTagV,"UB%02d",iDet);
030b4415 389 parCha[0] = fCwidth[iplan]/2.0 - fgkCalT;
390 parCha[1] = -1.0;
391 parCha[2] = -1.0;
bd0f8685 392 gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
0a5f3331 393 // The glue around the radiator
394 sprintf(cTagV,"UX%02d",iDet);
030b4415 395 parCha[0] = fCwidth[iplan]/2.0 - fgkCalT - fgkCclsT;
0a5f3331 396 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0 - fgkCclfT;
397 parCha[2] = fgkCraH/2.0;
398 gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
399 // The inner part of radiator (air)
400 sprintf(cTagV,"UC%02d",iDet);
401 parCha[0] = fCwidth[iplan]/2.0 - fgkCalT - fgkCclsT - fgkCglT;
402 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0 - fgkCclfT - fgkCglT;
030b4415 403 parCha[2] = -1.0;
bd0f8685 404 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
405
0a5f3331 406 // The upper part of the readout chambers (amplification volume)
407 // The Wacosit frames
bd0f8685 408 sprintf(cTagV,"UD%02d",iDet);
030b4415 409 parCha[0] = fCwidth[iplan]/2.0 + fgkCroW;
410 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0;
411 parCha[2] = fgkCamH/2.0;
bd0f8685 412 fChamberUDboxd[iDet][0] = parCha[0];
413 fChamberUDboxd[iDet][1] = parCha[1];
414 fChamberUDboxd[iDet][2] = parCha[2];
415 gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
0a5f3331 416 // The inner part of the Wacosit frame (air)
bd0f8685 417 sprintf(cTagV,"UE%02d",iDet);
030b4415 418 parCha[0] = fCwidth[iplan]/2.0 + fgkCroW - fgkCcuT;
0a5f3331 419 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0 - fgkCcuT;
bd0f8685 420 parCha[2] = -1.;
421 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
0a5f3331 422
423 // The support structure (pad plane, back panel, readout boards)
bd0f8685 424 // The aluminum frames
425 sprintf(cTagV,"UF%02d",iDet);
030b4415 426 parCha[0] = fCwidth[iplan]/2.0 + fgkCroW;
427 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0;
428 parCha[2] = fgkCroH/2.0;
bd0f8685 429 fChamberUFboxd[iDet][0] = parCha[0];
430 fChamberUFboxd[iDet][1] = parCha[1];
431 fChamberUFboxd[iDet][2] = parCha[2];
432 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
433 // The inner part of the aluminum frames
434 sprintf(cTagV,"UG%02d",iDet);
030b4415 435 parCha[0] = fCwidth[iplan]/2.0 + fgkCroW - fgkCauT;
0a5f3331 436 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0 - fgkCauT;
030b4415 437 parCha[2] = -1.0;
bd0f8685 438 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
439
440 // The material layers inside the chambers
0a5f3331 441 // Rohacell layer (radiator)
030b4415 442 parCha[0] = -1.0;
443 parCha[1] = -1.0;
030b4415 444 parCha[2] = fgkRaThick/2.0;
bd0f8685 445 sprintf(cTagV,"UH%02d",iDet);
446 gMC->Gsvolu(cTagV,"BOX ",idtmed[1315-1],parCha,kNparCha);
bd0f8685 447 // Xe/Isobutane layer (drift volume)
0a5f3331 448 parCha[0] = fCwidth[iplan]/2.0 - fgkCalT - fgkCclsT;
449 parCha[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0 - fgkCclfT;
030b4415 450 parCha[2] = fgkDrThick/2.0;
bd0f8685 451 sprintf(cTagV,"UJ%02d",iDet);
452 gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
453 // Xe/Isobutane layer (amplification volume)
0a5f3331 454 parCha[0] = -1.0;
455 parCha[1] = -1.0;
030b4415 456 parCha[2] = fgkAmThick/2.0;
bd0f8685 457 sprintf(cTagV,"UK%02d",iDet);
458 gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
0a5f3331 459 // Cu layer (wire plane)
460 parCha[0] = -1.0;
461 parCha[1] = -1.0;
462 parCha[2] = fgkWrThick/2.0;
463 sprintf(cTagV,"UW%02d",iDet);
464 gMC->Gsvolu(cTagV,"BOX ",idtmed[1303-1],parCha,kNparCha);
bd0f8685 465 // Cu layer (pad plane)
0a5f3331 466 parCha[0] = -1.0;
467 parCha[1] = -1.0;
030b4415 468 parCha[2] = fgkCuThick/2.0;
bd0f8685 469 sprintf(cTagV,"UL%02d",iDet);
470 gMC->Gsvolu(cTagV,"BOX ",idtmed[1305-1],parCha,kNparCha);
0a5f3331 471 // Epoxy layer (glue)
472 parCha[0] = -1.0;
473 parCha[1] = -1.0;
474 parCha[2] = fgkGlThick/2.0;
475 sprintf(cTagV,"UY%02d",iDet);
476 gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
bd0f8685 477 // G10 layer (support structure / honeycomb)
0a5f3331 478 parCha[0] = -1.0;
479 parCha[1] = -1.0;
030b4415 480 parCha[2] = fgkSuThick/2.0;
bd0f8685 481 sprintf(cTagV,"UM%02d",iDet);
0a5f3331 482 gMC->Gsvolu(cTagV,"BOX ",idtmed[1310-1],parCha,kNparCha);
483 // G10 layer (PCB readout board)
484 parCha[0] = -1.0;
485 parCha[1] = -1.0;
a797f961 486 parCha[2] = fgkRpThick/2;
487 sprintf(cTagV,"UN%02d",iDet);
488 gMC->Gsvolu(cTagV,"BOX ",idtmed[1313-1],parCha,kNparCha);
0a5f3331 489 // Cu layer (traces in readout board)
490 parCha[0] = -1.0;
491 parCha[1] = -1.0;
030b4415 492 parCha[2] = fgkRcThick/2.0;
a797f961 493 sprintf(cTagV,"UO%02d",iDet);
494 gMC->Gsvolu(cTagV,"BOX ",idtmed[1306-1],parCha,kNparCha);
0a5f3331 495 // Cu layer (other material on in readout board)
496 parCha[0] = -1.0;
497 parCha[1] = -1.0;
498 parCha[2] = fgkRoThick/2.0;
499 sprintf(cTagV,"UV%02d",iDet);
500 gMC->Gsvolu(cTagV,"BOX ",idtmed[1304-1],parCha,kNparCha);
bd0f8685 501
502 // Position the layers in the chambers
030b4415 503 xpos = 0.0;
504 ypos = 0.0;
bd0f8685 505 // Lower part
506 // Rohacell layer (radiator)
507 zpos = fgkRaZpos;
508 sprintf(cTagV,"UH%02d",iDet);
509 sprintf(cTagM,"UC%02d",iDet);
510 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
bd0f8685 511 // Xe/Isobutane layer (drift volume)
512 zpos = fgkDrZpos;
513 sprintf(cTagV,"UJ%02d",iDet);
0a5f3331 514 sprintf(cTagM,"UB%02d",iDet);
bd0f8685 515 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
516 // Upper part
517 // Xe/Isobutane layer (amplification volume)
518 zpos = fgkAmZpos;
519 sprintf(cTagV,"UK%02d",iDet);
520 sprintf(cTagM,"UE%02d",iDet);
521 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 522 // Cu layer (wire plane inside amplification volume)
523 zpos = fgkWrZpos;
524 sprintf(cTagV,"UW%02d",iDet);
525 sprintf(cTagM,"UK%02d",iDet);
526 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
527 // Readout part + support plane
bd0f8685 528 // Cu layer (pad plane)
529 zpos = fgkCuZpos;
530 sprintf(cTagV,"UL%02d",iDet);
531 sprintf(cTagM,"UG%02d",iDet);
532 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 533 // Epoxy layer (glue)
534 zpos = fgkGlZpos;
535 sprintf(cTagV,"UY%02d",iDet);
536 sprintf(cTagM,"UG%02d",iDet);
537 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
bd0f8685 538 // G10 layer (support structure)
539 zpos = fgkSuZpos;
540 sprintf(cTagV,"UM%02d",iDet);
541 sprintf(cTagM,"UG%02d",iDet);
542 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 543 // G10 layer (PCB readout board)
a797f961 544 zpos = fgkRpZpos;
545 sprintf(cTagV,"UN%02d",iDet);
546 sprintf(cTagM,"UG%02d",iDet);
547 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 548 // Cu layer (traces in readout board)
a797f961 549 zpos = fgkRcZpos;
550 sprintf(cTagV,"UO%02d",iDet);
551 sprintf(cTagM,"UG%02d",iDet);
552 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 553 // Cu layer (other materials on readout board)
554 zpos = fgkRoZpos;
555 sprintf(cTagV,"UV%02d",iDet);
556 sprintf(cTagM,"UG%02d",iDet);
557 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
bd0f8685 558
559 // Position the inner volumes of the chambers in the frames
030b4415 560 xpos = 0.0;
561 ypos = 0.0;
0a5f3331 562 // The inner part of the radiator
030b4415 563 zpos = 0.0;
bd0f8685 564 sprintf(cTagV,"UC%02d",iDet);
0a5f3331 565 sprintf(cTagM,"UX%02d",iDet);
566 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
567 // The glue around the radiator
568 zpos = fgkCraH/2.0 - fgkCdrH/2.0 - fgkCraH/2.0;
569 sprintf(cTagV,"UX%02d",iDet);
bd0f8685 570 sprintf(cTagM,"UB%02d",iDet);
571 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 572 // The lower Wacosit frame inside the aluminum frame
573 zpos = 0.0;
bd0f8685 574 sprintf(cTagV,"UB%02d",iDet);
575 sprintf(cTagM,"UA%02d",iDet);
576 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
0a5f3331 577 // The inside of the upper Wacosit frame
578 zpos = 0.0;
bd0f8685 579 sprintf(cTagV,"UE%02d",iDet);
580 sprintf(cTagM,"UD%02d",iDet);
581 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
582 // The inside of the upper aluminum frame
0a5f3331 583 zpos = 0.0;
bd0f8685 584 sprintf(cTagV,"UG%02d",iDet);
585 sprintf(cTagM,"UF%02d",iDet);
586 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
587
588 // Position the frames of the chambers in the TRD mother volume
030b4415 589 xpos = 0.0;
afb9f880 590 ypos = fClength[iplan][0] + fClength[iplan][1] + fClength[iplan][2]/2.0;
bd0f8685 591 for (Int_t ic = 0; ic < icham; ic++) {
afb9f880 592 ypos -= fClength[iplan][ic];
bd0f8685 593 }
afb9f880 594 ypos -= fClength[iplan][icham]/2.0;
0a5f3331 595 zpos = fgkVrocsm + fgkSMpltT + fgkCraH/2.0 + fgkCdrH/2.0 - fgkSheight/2.0
a797f961 596 + iplan * (fgkCH + fgkVspace);
bd0f8685 597 // The lower aluminum frame, radiator + drift region
598 sprintf(cTagV,"UA%02d",iDet);
599 fChamberUAorig[iDet][0] = xpos;
600 fChamberUAorig[iDet][1] = ypos;
601 fChamberUAorig[iDet][2] = zpos;
602 // The upper G10 frame, amplification region
603 sprintf(cTagV,"UD%02d",iDet);
030b4415 604 zpos += fgkCamH/2.0 + fgkCraH/2.0 + fgkCdrH/2.0;
bd0f8685 605 fChamberUDorig[iDet][0] = xpos;
606 fChamberUDorig[iDet][1] = ypos;
607 fChamberUDorig[iDet][2] = zpos;
608 // The upper aluminum frame
609 sprintf(cTagV,"UF%02d",iDet);
030b4415 610 zpos += fgkCroH/2.0 + fgkCamH/2.0;
bd0f8685 611 fChamberUForig[iDet][0] = xpos;
612 fChamberUForig[iDet][1] = ypos;
613 fChamberUForig[iDet][2] = zpos;
614
615 }
616 }
617
618 // Create the volumes of the super module frame
619 CreateFrame(idtmed);
620
621 // Create the volumes of the services
622 CreateServices(idtmed);
623
624 for (Int_t icham = 0; icham < kNcham; icham++) {
625 for (Int_t iplan = 0; iplan < kNplan; iplan++) {
626 GroupChamber(iplan,icham,idtmed);
627 }
628 }
629
030b4415 630 xpos = 0.0;
631 ypos = 0.0;
632 zpos = 0.0;
bd0f8685 633 gMC->Gspos("UTI1",1,"UTS1",xpos,ypos,zpos,0,"ONLY");
634
030b4415 635 xpos = 0.0;
636 ypos = 0.0;
637 zpos = 0.0;
bd0f8685 638 gMC->Gspos("UTS1",1,"UTR1",xpos,ypos,zpos,0,"ONLY");
639
640 // Put the TRD volumes into the space frame mother volumes
641 // if enabled via status flag
030b4415 642 xpos = 0.0;
643 ypos = 0.0;
644 zpos = 0.0;
bd0f8685 645 for (Int_t isect = 0; isect < kNsect; isect++) {
646 if (fSMstatus[isect]) {
647 sprintf(cTagV,"BTRD%d",isect);
f9017ffb 648 gMC->Gspos("UTR1",1,cTagV,xpos,ypos,zpos,0,"ONLY");
bd0f8685 649 }
650 }
651
652}
653
654//_____________________________________________________________________________
655void AliTRDgeometry::CreateFrame(Int_t *idtmed)
656{
657 //
658 // Create the geometry of the frame of the supermodule
659 //
660 // Names of the TRD services volumina
661 //
662 // USRL Support rails for the chambers (Al)
663 // USxx Support cross bars between the chambers (Al)
0a5f3331 664 // USHx Horizontal connection between the cross bars (Al)
665 // USLx Long corner ledges (Al)
bd0f8685 666 //
667
668 Int_t iplan = 0;
669
670 Float_t xpos = 0.0;
671 Float_t ypos = 0.0;
672 Float_t zpos = 0.0;
673
674 Char_t cTagV[5];
0a5f3331 675 Char_t cTagM[5];
676
677 // The rotation matrices
678 const Int_t kNmatrix = 4;
679 Int_t matrix[kNmatrix];
680 gMC->Matrix(matrix[0], 100.0, 0.0, 90.0, 90.0, 10.0, 0.0);
681 gMC->Matrix(matrix[1], 80.0, 0.0, 90.0, 90.0, 10.0, 180.0);
682 gMC->Matrix(matrix[2], 90.0, 0.0, 0.0, 0.0, 90.0, 90.0);
683 gMC->Matrix(matrix[3], 90.0, 180.0, 0.0, 180.0, 90.0, 90.0);
bd0f8685 684
685 //
686 // The chamber support rails
687 //
688
030b4415 689 const Float_t kSRLwid = 2.00;
bd0f8685 690 const Float_t kSRLhgt = 2.3;
0a5f3331 691 const Float_t kSRLdst = 1.0;
bd0f8685 692 const Int_t kNparSRL = 3;
693 Float_t parSRL[kNparSRL];
0a5f3331 694 parSRL[0] = kSRLwid /2.0;
695 parSRL[1] = fgkSlength/2.0;
696 parSRL[2] = kSRLhgt /2.0;
bd0f8685 697 gMC->Gsvolu("USRL","BOX ",idtmed[1301-1],parSRL,kNparSRL);
698
699 xpos = 0.0;
700 ypos = 0.0;
701 zpos = 0.0;
702 for (iplan = 0; iplan < kNplan; iplan++) {
0a5f3331 703 xpos = fCwidth[iplan]/2.0 + kSRLwid/2.0 + kSRLdst;
bd0f8685 704 ypos = 0.0;
0a5f3331 705 zpos = fgkVrocsm + fgkSMpltT + fgkCraH + fgkCdrH + fgkCamH
706 - fgkSheight/2.0
bd0f8685 707 + iplan * (fgkCH + fgkVspace);
708 gMC->Gspos("USRL",iplan+1 ,"UTI1", xpos,ypos,zpos,0,"ONLY");
709 gMC->Gspos("USRL",iplan+1+ kNplan,"UTI1",-xpos,ypos,zpos,0,"ONLY");
bd0f8685 710 }
711
712 //
713 // The cross bars between the chambers
714 //
715
716 const Float_t kSCBwid = 1.0;
0a5f3331 717 const Float_t kSCBthk = 2.0;
718 const Float_t kSCHhgt = 0.3;
719
bd0f8685 720 const Int_t kNparSCB = 3;
721 Float_t parSCB[kNparSCB];
030b4415 722 parSCB[1] = kSCBwid/2.0;
0a5f3331 723 parSCB[2] = fgkCH /2.0 + fgkVspace/2.0 - kSCHhgt;
724
725 const Int_t kNparSCI = 3;
726 Float_t parSCI[kNparSCI];
727 parSCI[1] = -1;
bd0f8685 728
729 xpos = 0.0;
730 ypos = 0.0;
731 zpos = 0.0;
732 for (iplan = 0; iplan < kNplan; iplan++) {
733
0a5f3331 734 // The aluminum of the cross bars
030b4415 735 parSCB[0] = fCwidth[iplan]/2.0 + kSRLdst/2.0;
0a5f3331 736 sprintf(cTagV,"USF%01d",iplan);
bd0f8685 737 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCB,kNparSCB);
bd0f8685 738
0a5f3331 739 // The empty regions in the cross bars
740 Float_t thkSCB = kSCBthk;
741 if (iplan < 2) {
742 thkSCB *= 1.5;
743 }
744 parSCI[2] = parSCB[2] - thkSCB;
745 parSCI[0] = parSCB[0]/4.0 - kSCBthk;
746 sprintf(cTagV,"USI%01d",iplan);
747 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parSCI,kNparSCI);
bd0f8685 748
0a5f3331 749 sprintf(cTagV,"USI%01d",iplan);
750 sprintf(cTagM,"USF%01d",iplan);
751 ypos = 0.0;
752 zpos = 0.0;
753 xpos = parSCI[0] + thkSCB/2.0;
754 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
755 xpos = - parSCI[0] - thkSCB/2.0;
756 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
757 xpos = 3.0 * parSCI[0] + 1.5 * thkSCB;
758 gMC->Gspos(cTagV,3,cTagM,xpos,ypos,zpos,0,"ONLY");
759 xpos = - 3.0 * parSCI[0] - 1.5 * thkSCB;
760 gMC->Gspos(cTagV,4,cTagM,xpos,ypos,zpos,0,"ONLY");
761
762 sprintf(cTagV,"USF%01d",iplan);
bd0f8685 763 xpos = 0.0;
0a5f3331 764 zpos = fgkVrocsm + fgkSMpltT + parSCB[2] - fgkSheight/2.0
765 + iplan * (fgkCH + fgkVspace);
766
767 ypos = fgkSlength/2.0 - kSCBwid/2.0;
bd0f8685 768 gMC->Gspos(cTagV,1,"UTI1", xpos,ypos,zpos,0,"ONLY");
769
0a5f3331 770 ypos = fClength[iplan][2]/2.0 + fClength[iplan][1];
771 gMC->Gspos(cTagV,2,"UTI1", xpos,ypos,zpos,0,"ONLY");
772
773 ypos = fClength[iplan][2]/2.0;
774 gMC->Gspos(cTagV,3,"UTI1", xpos,ypos,zpos,0,"ONLY");
775
030b4415 776 ypos = - fClength[iplan][2]/2.0;
0a5f3331 777 gMC->Gspos(cTagV,4,"UTI1", xpos,ypos,zpos,0,"ONLY");
bd0f8685 778
030b4415 779 ypos = - fClength[iplan][2]/2.0 - fClength[iplan][1];
0a5f3331 780 gMC->Gspos(cTagV,5,"UTI1", xpos,ypos,zpos,0,"ONLY");
bd0f8685 781
0a5f3331 782 ypos = - fgkSlength/2.0 + kSCBwid/2.0;
783 gMC->Gspos(cTagV,6,"UTI1", xpos,ypos,zpos,0,"ONLY");
784
785 }
786
787 //
788 // The horizontal connections between the cross bars
789 //
790
791 const Int_t kNparSCH = 3;
792 Float_t parSCH[kNparSCH];
793
794 for (iplan = 1; iplan < kNplan-1; iplan++) {
795
796 parSCH[0] = fCwidth[iplan]/2.0;
797 parSCH[1] = (fClength[iplan+1][2]/2.0 + fClength[iplan+1][1]
798 - fClength[iplan ][2]/2.0 - fClength[iplan ][1])/2.0;
799 parSCH[2] = kSCHhgt/2.0;
800
801 sprintf(cTagV,"USH%01d",iplan);
802 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCH,kNparSCH);
bd0f8685 803 xpos = 0.0;
0a5f3331 804 ypos = fClength[iplan][2]/2.0 + fClength[iplan][1] + parSCH[1];
805 zpos = fgkVrocsm + fgkSMpltT - kSCHhgt/2.0 - fgkSheight/2.0
806 + (iplan+1) * (fgkCH + fgkVspace);
bd0f8685 807 gMC->Gspos(cTagV,1,"UTI1", xpos,ypos,zpos,0,"ONLY");
0a5f3331 808 ypos = -ypos;
809 gMC->Gspos(cTagV,2,"UTI1", xpos,ypos,zpos,0,"ONLY");
bd0f8685 810
811 }
812
0a5f3331 813 //
814 // The long corner ledges
815 //
816
817 const Int_t kNparSCL = 3;
818 Float_t parSCL[kNparSCL];
819 const Int_t kNparSCLb = 11;
820 Float_t parSCLb[kNparSCLb];
821
822 // Upper ledges
823 // Thickness of the corner ledges
824 const Float_t kSCLthkUa = 0.6;
825 const Float_t kSCLthkUb = 0.6;
826 // Width of the corner ledges
827 const Float_t kSCLwidUa = 3.2;
828 const Float_t kSCLwidUb = 4.8;
829 // Position of the corner ledges
830 const Float_t kSCLposxUa = 0.7;
831 const Float_t kSCLposxUb = 3.3;
832 const Float_t kSCLposzUa = 1.6;
833 const Float_t kSCLposzUb = 0.3;
834 // Vertical
835 parSCL[0] = kSCLthkUa /2.0;
836 parSCL[1] = fgkSlength/2.0;
837 parSCL[2] = kSCLwidUa /2.0;
838 gMC->Gsvolu("USL1","BOX ",idtmed[1301-1],parSCL,kNparSCL);
839 xpos = fgkSwidth2/2.0 - fgkSMpltT - kSCLposxUa;
840 ypos = 0.0;
841 zpos = fgkSheight/2.0 - fgkSMpltT - kSCLposzUa;
842 gMC->Gspos("USL1",1,"UTI1", xpos,ypos,zpos,matrix[0],"ONLY");
843 xpos = -xpos;
844 gMC->Gspos("USL1",2,"UTI1", xpos,ypos,zpos,matrix[1],"ONLY");
845 // Horizontal
846 parSCL[0] = kSCLwidUb /2.0;
847 parSCL[1] = fgkSlength/2.0;
848 parSCL[2] = kSCLthkUb /2.0;
849 gMC->Gsvolu("USL2","BOX ",idtmed[1301-1],parSCL,kNparSCL);
850 xpos = fgkSwidth2/2.0 - fgkSMpltT - kSCLposxUb;
851 ypos = 0.0;
852 zpos = fgkSheight/2.0 - fgkSMpltT - kSCLposzUb;
853 gMC->Gspos("USL2",1,"UTI1", xpos,ypos,zpos, 0,"ONLY");
854 xpos = -xpos;
855 gMC->Gspos("USL2",2,"UTI1", xpos,ypos,zpos, 0,"ONLY");
856
857 // Lower ledges
858 // Thickness of the corner ledges
859 const Float_t kSCLthkLa = 2.464;
860 const Float_t kSCLthkLb = 1.0;
861 // Width of the corner ledges
862 const Float_t kSCLwidLa = 8.5;
863 const Float_t kSCLwidLb = 3.3;
864 // Position of the corner ledges
865 const Float_t kSCLposxLa = 0.0;
866 const Float_t kSCLposxLb = 2.6;
867 const Float_t kSCLposzLa = -4.25;
868 const Float_t kSCLposzLb = -0.5;
869 // Vertical
870 // Trapezoidal shape
871 parSCLb[ 0] = fgkSlength/2.0;
872 parSCLb[ 1] = 0.0;
873 parSCLb[ 2] = 0.0;
874 parSCLb[ 3] = kSCLwidLa /2.0;
875 parSCLb[ 4] = kSCLthkLb /2.0;
876 parSCLb[ 5] = kSCLthkLa /2.0;
877 parSCLb[ 6] = 5.0;
878 parSCLb[ 7] = kSCLwidLa /2.0;
879 parSCLb[ 8] = kSCLthkLb /2.0;
880 parSCLb[ 9] = kSCLthkLa /2.0;
881 parSCLb[10] = 5.0;
882 gMC->Gsvolu("USL3","TRAP",idtmed[1301-1],parSCLb,kNparSCLb);
883 xpos = fgkSwidth1/2.0 - fgkSMpltT - kSCLposxLa;
884 ypos = 0.0;
885 zpos = - fgkSheight/2.0 + fgkSMpltT - kSCLposzLa;
886 gMC->Gspos("USL3",1,"UTI1", xpos,ypos,zpos,matrix[2],"ONLY");
887 xpos = -xpos;
888 gMC->Gspos("USL3",2,"UTI1", xpos,ypos,zpos,matrix[3],"ONLY");
889 // Horizontal
890 parSCL[0] = kSCLwidLb /2.0;
891 parSCL[1] = fgkSlength/2.0;
892 parSCL[2] = kSCLthkLb /2.0;
893 gMC->Gsvolu("USL4","BOX ",idtmed[1301-1],parSCL,kNparSCL);
894 xpos = fgkSwidth1/2.0 - fgkSMpltT - kSCLposxLb;
895 ypos = 0.0;
896 zpos = - fgkSheight/2.0 + fgkSMpltT - kSCLposzLb;
897 gMC->Gspos("USL4",1,"UTI1", xpos,ypos,zpos, 0,"ONLY");
898 xpos = -xpos;
899 gMC->Gspos("USL4",2,"UTI1", xpos,ypos,zpos, 0,"ONLY");
900
bd0f8685 901}
902
903//_____________________________________________________________________________
904void AliTRDgeometry::CreateServices(Int_t *idtmed)
905{
906 //
907 // Create the geometry of the services
908 //
909 // Names of the TRD services volumina
910 //
911 // UTCL Cooling arterias (Al)
912 // UTCW Cooling arterias (Water)
913 // UUxx Volumes for the services at the chambers (Air)
914 // UTPW Power bars (Cu)
0a5f3331 915 // UTCP Cooling pipes (Fe)
bd0f8685 916 // UTCH Cooling pipes (Water)
917 // UTPL Power lines (Cu)
918 // UMCM Readout MCMs (G10/Cu/Si)
919 //
920
921 Int_t iplan = 0;
922 Int_t icham = 0;
923
924 Float_t xpos = 0.0;
925 Float_t ypos = 0.0;
926 Float_t zpos = 0.0;
927
928 Char_t cTagV[5];
929
930 // The rotation matrices
99ed5146 931 const Int_t kNmatrix = 4;
bd0f8685 932 Int_t matrix[kNmatrix];
030b4415 933 gMC->Matrix(matrix[0], 100.0, 0.0, 90.0, 90.0, 10.0, 0.0);
934 gMC->Matrix(matrix[1], 80.0, 0.0, 90.0, 90.0, 10.0, 180.0);
935 gMC->Matrix(matrix[2], 0.0, 0.0, 90.0, 90.0, 90.0, 0.0);
99ed5146 936 gMC->Matrix(matrix[3], 180.0, 0.0, 90.0, 90.0, 90.0, 180.0);
bd0f8685 937
030b4415 938 AliTRDCommonParam *commonParam = AliTRDCommonParam::Instance();
2745a409 939 if (!commonParam) {
940 AliError("Could not get common parameters\n");
bd0f8685 941 return;
942 }
943
944 //
945 // The cooling arterias
946 //
947
948 // Width of the cooling arterias
0a5f3331 949 const Float_t kCOLwid = 0.8;
bd0f8685 950 // Height of the cooling arterias
0a5f3331 951 const Float_t kCOLhgt = 6.5;
bd0f8685 952 // Positioning of the cooling
0a5f3331 953 const Float_t kCOLposx = 1.8;
954 const Float_t kCOLposz = -0.1;
bd0f8685 955 // Thickness of the walls of the cooling arterias
956 const Float_t kCOLthk = 0.1;
030b4415 957 const Int_t kNparCOL = 3;
bd0f8685 958 Float_t parCOL[kNparCOL];
0a5f3331 959 parCOL[0] = kCOLwid /2.0;
960 parCOL[1] = fgkSlength/2.0;
961 parCOL[2] = kCOLhgt /2.0;
962 gMC->Gsvolu("UTCL","BOX ",idtmed[1308-1],parCOL,kNparCOL);
bd0f8685 963 parCOL[0] -= kCOLthk;
0a5f3331 964 parCOL[1] = fgkSlength/2.0;
bd0f8685 965 parCOL[2] -= kCOLthk;
966 gMC->Gsvolu("UTCW","BOX ",idtmed[1314-1],parCOL,kNparCOL);
967
968 xpos = 0.0;
969 ypos = 0.0;
970 zpos = 0.0;
971 gMC->Gspos("UTCW",1,"UTCL", xpos,ypos,zpos,0,"ONLY");
972
99ed5146 973 for (iplan = 1; iplan < kNplan; iplan++) {
974
030b4415 975 xpos = fCwidth[iplan]/2.0 + kCOLwid/2.0 + kCOLposx;
bd0f8685 976 ypos = 0.0;
0a5f3331 977 zpos = fgkVrocsm + fgkSMpltT + kCOLhgt/2.0 - fgkSheight/2.0 + kCOLposz
a797f961 978 + iplan * (fgkCH + fgkVspace);
99ed5146 979 gMC->Gspos("UTCL",iplan ,"UTI1", xpos,ypos,zpos,matrix[0],"ONLY");
980 gMC->Gspos("UTCL",iplan+kNplan,"UTI1",-xpos,ypos,zpos,matrix[1],"ONLY");
981
bd0f8685 982 }
983
99ed5146 984 // The upper most layer (reaching into TOF acceptance)
0a5f3331 985 xpos = fCwidth[5]/2.0 - kCOLhgt/2.0 - 1.3;
99ed5146 986 ypos = 0.0;
0a5f3331 987 zpos = fgkSheight/2.0 - fgkSMpltT - 0.4 - kCOLwid/2.0;
99ed5146 988 gMC->Gspos("UTCL",6 ,"UTI1", xpos,ypos,zpos,matrix[3],"ONLY");
989 gMC->Gspos("UTCL",6+kNplan,"UTI1",-xpos,ypos,zpos,matrix[3],"ONLY");
990
bd0f8685 991 //
992 // The power bars
993 //
994
995 const Float_t kPWRwid = 0.6;
0a5f3331 996 const Float_t kPWRhgt = 5.0;
997 const Float_t kPWRposx = 1.4;
998 const Float_t kPWRposz = 1.9;
030b4415 999 const Int_t kNparPWR = 3;
bd0f8685 1000 Float_t parPWR[kNparPWR];
0a5f3331 1001 parPWR[0] = kPWRwid /2.0;
1002 parPWR[1] = fgkSlength/2.0;
1003 parPWR[2] = kPWRhgt /2.0;
bd0f8685 1004 gMC->Gsvolu("UTPW","BOX ",idtmed[1325-1],parPWR,kNparPWR);
1005
99ed5146 1006 for (iplan = 1; iplan < kNplan; iplan++) {
bd0f8685 1007
030b4415 1008 xpos = fCwidth[iplan]/2.0 + kPWRwid/2.0 + kPWRposx;
bd0f8685 1009 ypos = 0.0;
0a5f3331 1010 zpos = fgkVrocsm + fgkSMpltT + kPWRhgt/2.0 - fgkSheight/2.0 + kPWRposz
a797f961 1011 + iplan * (fgkCH + fgkVspace);
99ed5146 1012 gMC->Gspos("UTPW",iplan ,"UTI1", xpos,ypos,zpos,matrix[0],"ONLY");
1013 gMC->Gspos("UTPW",iplan+kNplan,"UTI1",-xpos,ypos,zpos,matrix[1],"ONLY");
bd0f8685 1014
1015 }
1016
99ed5146 1017 // The upper most layer (reaching into TOF acceptance)
0a5f3331 1018 xpos = fCwidth[5]/2.0 + kPWRhgt/2.0 - 1.3;
99ed5146 1019 ypos = 0.0;
0a5f3331 1020 zpos = fgkSheight/2.0 - fgkSMpltT - 0.6 - kPWRwid/2.0;
99ed5146 1021 gMC->Gspos("UTPW",6 ,"UTI1", xpos,ypos,zpos,matrix[3],"ONLY");
1022 gMC->Gspos("UTPW",6+kNplan,"UTI1",-xpos,ypos,zpos,matrix[3],"ONLY");
1023
bd0f8685 1024 //
1025 // The volumes for the services at the chambers
1026 //
1027
1028 const Int_t kNparServ = 3;
1029 Float_t parServ[kNparServ];
1030
1031 for (icham = 0; icham < kNcham; icham++) {
1032 for (iplan = 0; iplan < kNplan; iplan++) {
bd0f8685 1033
1034 Int_t iDet = GetDetectorSec(iplan,icham);
1035
1036 sprintf(cTagV,"UU%02d",iDet);
0a5f3331 1037 parServ[0] = fCwidth[iplan] /2.0;
030b4415 1038 parServ[1] = fClength[iplan][icham]/2.0 - fgkHspace/2.0;
0a5f3331 1039 parServ[2] = fgkVspace /2.0 - 0.742/2.0;
bd0f8685 1040 fChamberUUboxd[iDet][0] = parServ[0];
1041 fChamberUUboxd[iDet][1] = parServ[1];
1042 fChamberUUboxd[iDet][2] = parServ[2];
bd0f8685 1043 gMC->Gsvolu(cTagV,"BOX",idtmed[1302-1],parServ,kNparServ);
a797f961 1044
0a5f3331 1045 xpos = 0.0;
afb9f880 1046 ypos = fClength[iplan][0] + fClength[iplan][1] + fClength[iplan][2]/2.0;
bd0f8685 1047 for (Int_t ic = 0; ic < icham; ic++) {
afb9f880 1048 ypos -= fClength[iplan][ic];
bd0f8685 1049 }
afb9f880 1050 ypos -= fClength[iplan][icham]/2.0;
0a5f3331 1051 zpos = fgkVrocsm + fgkSMpltT + fgkCH + fgkVspace/2.0 - fgkSheight/2.0
a797f961 1052 + iplan * (fgkCH + fgkVspace);
030b4415 1053 zpos -= 0.742/2.0;
bd0f8685 1054 fChamberUUorig[iDet][0] = xpos;
1055 fChamberUUorig[iDet][1] = ypos;
1056 fChamberUUorig[iDet][2] = zpos;
1057
1058 }
1059 }
1060
1061 //
1062 // The cooling pipes inside the service volumes
1063 //
1064
1065 const Int_t kNparTube = 3;
1066 Float_t parTube[kNparTube];
0a5f3331 1067 // The cooling pipes
bd0f8685 1068 parTube[0] = 0.0;
1069 parTube[1] = 0.0;
1070 parTube[2] = 0.0;
1071 gMC->Gsvolu("UTCP","TUBE",idtmed[1324-1],parTube,0);
1072 // The cooling water
1073 parTube[0] = 0.0;
030b4415 1074 parTube[1] = 0.2/2.0;
bd0f8685 1075 parTube[2] = -1.;
1076 gMC->Gsvolu("UTCH","TUBE",idtmed[1314-1],parTube,kNparTube);
1077 // Water inside the cooling pipe
1078 xpos = 0.0;
1079 ypos = 0.0;
1080 zpos = 0.0;
1081 gMC->Gspos("UTCH",1,"UTCP",xpos,ypos,zpos,0,"ONLY");
1082
1083 // Position the cooling pipes in the mother volume
1084 const Int_t kNpar = 3;
1085 Float_t par[kNpar];
1086 for (icham = 0; icham < kNcham; icham++) {
1087 for (iplan = 0; iplan < kNplan; iplan++) {
bd0f8685 1088 Int_t iDet = GetDetectorSec(iplan,icham);
1089 Int_t iCopy = GetDetector(iplan,icham,0) * 100;
1090 Int_t nMCMrow = commonParam->GetRowMax(iplan,icham,0);
030b4415 1091 Float_t ySize = (GetChamberLength(iplan,icham) - 2.0*fgkRpadW)
bd0f8685 1092 / ((Float_t) nMCMrow);
1093 sprintf(cTagV,"UU%02d",iDet);
1094 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
1095 xpos = 0.0;
1096 ypos = (0.5 + iMCMrow) * ySize - 1.9
030b4415 1097 - fClength[iplan][icham]/2.0 + fgkHspace/2.0;
1098 zpos = 0.0 + 0.742/2.0;
bd0f8685 1099 par[0] = 0.0;
030b4415 1100 par[1] = 0.3/2.0; // Thickness of the cooling pipes
1101 par[2] = fCwidth[iplan]/2.0;
bd0f8685 1102 gMC->Gsposp("UTCP",iCopy+iMCMrow,cTagV,xpos,ypos,zpos
1103 ,matrix[2],"ONLY",par,kNpar);
1104 }
1105 }
1106 }
1107
1108 //
1109 // The power lines
1110 //
1111
1112 // The copper power lines
1113 parTube[0] = 0.0;
1114 parTube[1] = 0.0;
1115 parTube[2] = 0.0;
1116 gMC->Gsvolu("UTPL","TUBE",idtmed[1305-1],parTube,0);
1117
1118 // Position the power lines in the mother volume
1119 for (icham = 0; icham < kNcham; icham++) {
1120 for (iplan = 0; iplan < kNplan; iplan++) {
bd0f8685 1121 Int_t iDet = GetDetectorSec(iplan,icham);
1122 Int_t iCopy = GetDetector(iplan,icham,0) * 100;
1123 Int_t nMCMrow = commonParam->GetRowMax(iplan,icham,0);
030b4415 1124 Float_t ySize = (GetChamberLength(iplan,icham) - 2.0*fgkRpadW)
bd0f8685 1125 / ((Float_t) nMCMrow);
1126 sprintf(cTagV,"UU%02d",iDet);
1127 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
1128 xpos = 0.0;
1129 ypos = (0.5 + iMCMrow) * ySize - 1.0
030b4415 1130 - fClength[iplan][icham]/2.0 + fgkHspace/2.0;
1131 zpos = -0.4 + 0.742/2.0;
bd0f8685 1132 par[0] = 0.0;
030b4415 1133 par[1] = 0.2/2.0; // Thickness of the power lines
1134 par[2] = fCwidth[iplan]/2.0;
bd0f8685 1135 gMC->Gsposp("UTPL",iCopy+iMCMrow,cTagV,xpos,ypos,zpos
1136 ,matrix[2],"ONLY",par,kNpar);
1137 }
1138 }
1139 }
1140
1141 //
1142 // The MCMs
1143 //
1144
0a5f3331 1145 const Float_t kMCMx = 3.0;
1146 const Float_t kMCMy = 3.0;
1147 const Float_t kMCMz = 0.3;
1148
1149 const Float_t kMCMpcTh = 0.1;
1150 const Float_t kMCMcuTh = 0.0215;
1151 const Float_t kMCMsiTh = 0.003;
1152 const Float_t kMCMcoTh = 0.1549;
1153
bd0f8685 1154 // The mother volume for the MCMs (air)
1155 const Int_t kNparMCM = 3;
1156 Float_t parMCM[kNparMCM];
0a5f3331 1157 parMCM[0] = kMCMx /2.0;
1158 parMCM[1] = kMCMy /2.0;
1159 parMCM[2] = kMCMz /2.0;
bd0f8685 1160 gMC->Gsvolu("UMCM","BOX",idtmed[1302-1],parMCM,kNparMCM);
1161
1162 // The MCM carrier G10 layer
0a5f3331 1163 parMCM[0] = kMCMx /2.0;
1164 parMCM[1] = kMCMy /2.0;
1165 parMCM[2] = kMCMpcTh/2.0;
bd0f8685 1166 gMC->Gsvolu("UMC1","BOX",idtmed[1319-1],parMCM,kNparMCM);
1167 // The MCM carrier Cu layer
0a5f3331 1168 parMCM[0] = kMCMx /2.0;
1169 parMCM[1] = kMCMy /2.0;
1170 parMCM[2] = kMCMcuTh/2.0;
bd0f8685 1171 gMC->Gsvolu("UMC2","BOX",idtmed[1318-1],parMCM,kNparMCM);
1172 // The silicon of the chips
0a5f3331 1173 parMCM[0] = kMCMx /2.0;
1174 parMCM[1] = kMCMy /2.0;
1175 parMCM[2] = kMCMsiTh/2.0;
bd0f8685 1176 gMC->Gsvolu("UMC3","BOX",idtmed[1320-1],parMCM,kNparMCM);
0a5f3331 1177 // The aluminum of the cooling plates
1178 parMCM[0] = kMCMx /2.0;
1179 parMCM[1] = kMCMy /2.0;
1180 parMCM[2] = kMCMcoTh/2.0;
1181 gMC->Gsvolu("UMC4","BOX",idtmed[1324-1],parMCM,kNparMCM);
bd0f8685 1182
1183 // Put the MCM material inside the MCM mother volume
1184 xpos = 0.0;
1185 ypos = 0.0;
0a5f3331 1186 zpos = -kMCMz /2.0 + kMCMpcTh/2.0;
bd0f8685 1187 gMC->Gspos("UMC1",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
0a5f3331 1188 zpos += kMCMpcTh/2.0 + kMCMcuTh/2.0;
bd0f8685 1189 gMC->Gspos("UMC2",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
0a5f3331 1190 zpos += kMCMcuTh/2.0 + kMCMsiTh/2.0;
bd0f8685 1191 gMC->Gspos("UMC3",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
0a5f3331 1192 zpos += kMCMsiTh/2.0 + kMCMcoTh/2.0;
1193 gMC->Gspos("UMC4",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
bd0f8685 1194
1195 // Position the MCMs in the mother volume
1196 for (icham = 0; icham < kNcham; icham++) {
1197 for (iplan = 0; iplan < kNplan; iplan++) {
bd0f8685 1198 Int_t iDet = GetDetectorSec(iplan,icham);
1199 Int_t iCopy = GetDetector(iplan,icham,0) * 1000;
1200 Int_t nMCMrow = commonParam->GetRowMax(iplan,icham,0);
030b4415 1201 Float_t ySize = (GetChamberLength(iplan,icham) - 2.0*fgkRpadW)
bd0f8685 1202 / ((Float_t) nMCMrow);
1203 Int_t nMCMcol = 8;
0a5f3331 1204 Float_t xSize = (GetChamberWidth(iplan) - 2.0*fgkCpadW)
bd0f8685 1205 / ((Float_t) nMCMcol);
1206 sprintf(cTagV,"UU%02d",iDet);
1207 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
1208 for (Int_t iMCMcol = 0; iMCMcol < nMCMcol; iMCMcol++) {
1209 xpos = (0.5 + iMCMcol) * xSize + 1.0
030b4415 1210 - fCwidth[iplan]/2.0;
bd0f8685 1211 ypos = (0.5 + iMCMrow) * ySize + 1.0
030b4415 1212 - fClength[iplan][icham]/2.0 + fgkHspace/2.0;
1213 zpos = -0.4 + 0.742/2.0;
bd0f8685 1214 par[0] = 0.0;
030b4415 1215 par[1] = 0.2/2.0; // Thickness of the power lines
1216 par[2] = fCwidth[iplan]/2.0;
bd0f8685 1217 gMC->Gspos("UMCM",iCopy+iMCMrow*10+iMCMcol,cTagV
1218 ,xpos,ypos,zpos,0,"ONLY");
1219 }
1220 }
1221
1222 }
1223 }
1224
1225}
1226
1227//_____________________________________________________________________________
1228void AliTRDgeometry::GroupChamber(Int_t iplan, Int_t icham, Int_t *idtmed)
f7336fa3 1229{
1230 //
bd0f8685 1231 // Group volumes UA, UD, UF, UU in a single chamber (Air)
1232 // UA, UD, UF, UU are boxes
1233 // UT will be a box
0a770ac9 1234 //
bd0f8685 1235
1236 const Int_t kNparCha = 3;
1237
1238 Int_t iDet = GetDetectorSec(iplan,icham);
1239
1240 Float_t xyzMin[3];
1241 Float_t xyzMax[3];
1242 Float_t xyzOrig[3];
1243 Float_t xyzBoxd[3];
1244
1245 Char_t cTagV[5];
1246 Char_t cTagM[5];
1247
1248 for (Int_t i = 0; i < 3; i++) {
030b4415 1249 xyzMin[i] = +9999.0;
1250 xyzMax[i] = -9999.0;
bd0f8685 1251 }
1252
1253 for (Int_t i = 0; i < 3; i++) {
1254
1255 xyzMin[i] = TMath::Min(xyzMin[i],fChamberUAorig[iDet][i]-fChamberUAboxd[iDet][i]);
1256 xyzMax[i] = TMath::Max(xyzMax[i],fChamberUAorig[iDet][i]+fChamberUAboxd[iDet][i]);
1257
1258 xyzMin[i] = TMath::Min(xyzMin[i],fChamberUDorig[iDet][i]-fChamberUDboxd[iDet][i]);
1259 xyzMax[i] = TMath::Max(xyzMax[i],fChamberUDorig[iDet][i]+fChamberUDboxd[iDet][i]);
1260
1261 xyzMin[i] = TMath::Min(xyzMin[i],fChamberUForig[iDet][i]-fChamberUFboxd[iDet][i]);
1262 xyzMax[i] = TMath::Max(xyzMax[i],fChamberUForig[iDet][i]+fChamberUFboxd[iDet][i]);
1263
a797f961 1264 xyzMin[i] = TMath::Min(xyzMin[i],fChamberUUorig[iDet][i]-fChamberUUboxd[iDet][i]);
1265 xyzMax[i] = TMath::Max(xyzMax[i],fChamberUUorig[iDet][i]+fChamberUUboxd[iDet][i]);
bd0f8685 1266
1267 xyzOrig[i] = 0.5*(xyzMax[i]+xyzMin[i]);
1268 xyzBoxd[i] = 0.5*(xyzMax[i]-xyzMin[i]);
1269
1270 }
1271
1272 sprintf(cTagM,"UT%02d",iDet);
bd0f8685 1273 gMC->Gsvolu(cTagM,"BOX ",idtmed[1302-1],xyzBoxd,kNparCha);
1274
1275 sprintf(cTagV,"UA%02d",iDet);
0a5f3331 1276 gMC->Gspos(cTagV,1,cTagM
1277 ,fChamberUAorig[iDet][0]-xyzOrig[0]
1278 ,fChamberUAorig[iDet][1]-xyzOrig[1]
1279 ,fChamberUAorig[iDet][2]-xyzOrig[2]
1280 ,0,"ONLY");
1281
1282 sprintf(cTagV,"UZ%02d",iDet);
1283 gMC->Gspos(cTagV,1,cTagM
1284 ,fChamberUAorig[iDet][0]-xyzOrig[0] + fChamberUAboxd[iDet][0] - fgkCroW/2.0
1285 ,fChamberUAorig[iDet][1]-xyzOrig[1]
1286 ,fChamberUAorig[iDet][2]-xyzOrig[2] + fgkCraH/2.0 + fgkCdrH/2.0 - fgkCalW/2.0
1287 ,0,"ONLY");
1288 gMC->Gspos(cTagV,2,cTagM
1289 ,fChamberUAorig[iDet][0]-xyzOrig[0] - fChamberUAboxd[iDet][0] + fgkCroW/2.0
1290 ,fChamberUAorig[iDet][1]-xyzOrig[1]
1291 ,fChamberUAorig[iDet][2]-xyzOrig[2] + fgkCraH/2.0 + fgkCdrH/2.0 - fgkCalW/2.0
1292 ,0,"ONLY");
bd0f8685 1293
1294 sprintf(cTagV,"UD%02d",iDet);
0a5f3331 1295 gMC->Gspos(cTagV,1,cTagM
1296 ,fChamberUDorig[iDet][0]-xyzOrig[0]
1297 ,fChamberUDorig[iDet][1]-xyzOrig[1]
1298 ,fChamberUDorig[iDet][2]-xyzOrig[2]
1299 ,0,"ONLY");
bd0f8685 1300
1301 sprintf(cTagV,"UF%02d",iDet);
0a5f3331 1302 gMC->Gspos(cTagV,1,cTagM
1303 ,fChamberUForig[iDet][0]-xyzOrig[0]
1304 ,fChamberUForig[iDet][1]-xyzOrig[1]
1305 ,fChamberUForig[iDet][2]-xyzOrig[2]
1306 ,0,"ONLY");
bd0f8685 1307
a797f961 1308 sprintf(cTagV,"UU%02d",iDet);
0a5f3331 1309 gMC->Gspos(cTagV,1,cTagM
1310 ,fChamberUUorig[iDet][0]-xyzOrig[0]
1311 ,fChamberUUorig[iDet][1]-xyzOrig[1]
1312 ,fChamberUUorig[iDet][2]-xyzOrig[2]
1313 ,0,"ONLY");
bd0f8685 1314
1315 sprintf(cTagV,"UT%02d",iDet);
0a5f3331 1316 gMC->Gspos(cTagV,1,"UTI1"
1317 ,xyzOrig[0]
1318 ,xyzOrig[1]
1319 ,xyzOrig[2]
1320 ,0,"ONLY");
f7336fa3 1321
1322}
1323
f7336fa3 1324//_____________________________________________________________________________
a5cadd36 1325Bool_t AliTRDgeometry::Rotate(Int_t d, Double_t *pos, Double_t *rot) const
f7336fa3 1326{
1327 //
1328 // Rotates all chambers in the position of sector 0 and transforms
1329 // the coordinates in the ALICE restframe <pos> into the
1330 // corresponding local frame <rot>.
1331 //
1332
793ff80c 1333 Int_t sector = GetSector(d);
f7336fa3 1334
793ff80c 1335 rot[0] = pos[0] * fRotA11[sector] + pos[1] * fRotA12[sector];
1336 rot[1] = -pos[0] * fRotA21[sector] + pos[1] * fRotA22[sector];
f7336fa3 1337 rot[2] = pos[2];
1338
1339 return kTRUE;
1340
1341}
1342
1343//_____________________________________________________________________________
a5cadd36 1344Bool_t AliTRDgeometry::RotateBack(Int_t d, Double_t *rot, Double_t *pos) const
f7336fa3 1345{
1346 //
1347 // Rotates a chambers from the position of sector 0 into its
1348 // original position and transforms the corresponding local frame
1349 // coordinates <rot> into the coordinates of the ALICE restframe <pos>.
1350 //
1351
793ff80c 1352 Int_t sector = GetSector(d);
f7336fa3 1353
793ff80c 1354 pos[0] = rot[0] * fRotB11[sector] + rot[1] * fRotB12[sector];
1355 pos[1] = -rot[0] * fRotB21[sector] + rot[1] * fRotB22[sector];
6f1e466d 1356 pos[2] = rot[2];
f7336fa3 1357
1358 return kTRUE;
1359
1360}
1361
1362//_____________________________________________________________________________
3551db50 1363Int_t AliTRDgeometry::GetDetectorSec(Int_t p, Int_t c)
0a770ac9 1364{
1365 //
1366 // Convert plane / chamber into detector number for one single sector
1367 //
1368
1369 return (p + c * fgkNplan);
1370
1371}
1372
1373//_____________________________________________________________________________
3551db50 1374Int_t AliTRDgeometry::GetDetector(Int_t p, Int_t c, Int_t s)
f7336fa3 1375{
1376 //
1377 // Convert plane / chamber / sector into detector number
1378 //
1379
793ff80c 1380 return (p + c * fgkNplan + s * fgkNplan * fgkNcham);
f7336fa3 1381
1382}
1383
1384//_____________________________________________________________________________
afc51ac2 1385Int_t AliTRDgeometry::GetPlane(Int_t d) const
f7336fa3 1386{
1387 //
1388 // Reconstruct the plane number from the detector number
1389 //
1390
793ff80c 1391 return ((Int_t) (d % fgkNplan));
f7336fa3 1392
1393}
1394
1395//_____________________________________________________________________________
afc51ac2 1396Int_t AliTRDgeometry::GetChamber(Int_t d) const
f7336fa3 1397{
1398 //
1399 // Reconstruct the chamber number from the detector number
1400 //
1401
793ff80c 1402 return ((Int_t) (d % (fgkNplan * fgkNcham)) / fgkNplan);
f7336fa3 1403
1404}
1405
1406//_____________________________________________________________________________
afc51ac2 1407Int_t AliTRDgeometry::GetSector(Int_t d) const
f7336fa3 1408{
1409 //
1410 // Reconstruct the sector number from the detector number
1411 //
1412
793ff80c 1413 return ((Int_t) (d / (fgkNplan * fgkNcham)));
f7336fa3 1414
1415}
1416
7925de54 1417//_____________________________________________________________________________
bd63bf88 1418Int_t AliTRDgeometry::GetPadRowFromMCM(Int_t irob, Int_t imcm) const
7925de54 1419{
1420
1421 // return on which row this mcm sits
1422
1423 return fgkMCMrow*(irob/2) + imcm/fgkMCMrow;
1424
1425;
1426}
1427
1428//_____________________________________________________________________________
bd63bf88 1429Int_t AliTRDgeometry::GetPadColFromADC(Int_t irob, Int_t imcm, Int_t iadc) const
7925de54 1430{
1431 //
bd63bf88 1432 // return which pad is connected to this adc channel.
1433 //
1434 // ADC channels 2 to 19 are connected directly to a pad via PASA.
1435 // ADC channels 0, 1 and 20 are not connected to the PASA on this MCM.
1436 // So the mapping (for MCM 0 on ROB 0 at least) is
1437 //
1438 // ADC channel : 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
1439 // Pad : x x 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 x
1440 // Func. returns: 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 -1
1441 //
1442 // Here we assume that 21 ADC channels are transmitted. Maybe it will only be
1443 // 18 later on!!!
1444 //
1445 // This function maps also correctly the channels that cross from MCM to MCM
1446 // (ADC channels 0, 1, 20).
7925de54 1447 //
1448
bd63bf88 1449 return (17-(iadc-2)) + (imcm%fgkMCMrow)*fgkPadmax + GetRobSide(irob)*fgkColmax/2;
7925de54 1450
1451}
1452
1453//_____________________________________________________________________________
bd63bf88 1454Int_t AliTRDgeometry::GetMCMfromPad(Int_t irow, Int_t icol) const
7925de54 1455{
1456
1457 // return on which mcm this pad is
1458
1459 if ( irow < 0 || icol < 0 || irow > fgkRowmaxC1 || icol > fgkColmax ) return -1;
1460
1461 return (icol%(fgkColmax/2))/fgkPadmax + fgkMCMrow*(irow%fgkMCMrow);
1462
1463}
1464
1465//_____________________________________________________________________________
bd63bf88 1466Int_t AliTRDgeometry::GetROBfromPad(Int_t irow, Int_t icol) const
7925de54 1467{
1468
1469 // return on which rob this pad is
1470
1471 return (irow/fgkMCMrow)*2 + GetColSide(icol);
1472
1473}
1474
1475//_____________________________________________________________________________
1476Int_t AliTRDgeometry::GetRobSide(Int_t irob) const
1477{
1478
1479 // return on which side this rob sits (A side = 0, B side = 1)
1480
1481 if ( irob < 0 || irob >= fgkROBmaxC1 ) return -1;
1482
1483 return irob%2;
1484
1485}
1486
1487//_____________________________________________________________________________
1488Int_t AliTRDgeometry::GetColSide(Int_t icol) const
1489{
1490
1491 // return on which side this column sits (A side = 0, B side = 1)
1492
1493 if ( icol < 0 || icol >= fgkColmax ) return -1;
1494
1495 return icol/(fgkColmax/2);
1496
1497}
1498
bdbb05bb 1499//_____________________________________________________________________________
0a5f3331 1500AliTRDgeometry *AliTRDgeometry::GetGeometry(AliRunLoader *runLoader)
bdbb05bb 1501{
1502 //
030b4415 1503 // Load the geometry from the galice file
bdbb05bb 1504 //
1505
c965eab1 1506 if (!runLoader) {
1507 runLoader = AliRunLoader::GetRunLoader();
1508 }
bdbb05bb 1509 if (!runLoader) {
030b4415 1510 AliErrorGeneral("AliTRDgeometry::GetGeometry","No run loader");
bdbb05bb 1511 return NULL;
1512 }
1513
030b4415 1514 TDirectory *saveDir = gDirectory;
bdbb05bb 1515 runLoader->CdGAFile();
1516
ecb36af7 1517 // Try from the galice.root file
030b4415 1518 AliTRDgeometry *geom = (AliTRDgeometry *) gDirectory->Get("TRDgeometry");
ecb36af7 1519
1520 if (!geom) {
c965eab1 1521 // If it is not in the file, try to get it from the run loader
40609f3f 1522 if (runLoader->GetAliRun()) {
1523 AliTRD *trd = (AliTRD *) runLoader->GetAliRun()->GetDetector("TRD");
1524 if (trd) geom = trd->GetGeometry();
1525 }
ecb36af7 1526 }
2745a409 1527 if (!geom) {
030b4415 1528 AliErrorGeneral("AliTRDgeometry::GetGeometry","Geometry not found");
2745a409 1529 return NULL;
1530 }
bdbb05bb 1531
1532 saveDir->cd();
1533 return geom;
b4a9cd27 1534
bd0f8685 1535}
b4a9cd27 1536
1537//_____________________________________________________________________________
bd0f8685 1538Bool_t AliTRDgeometry::ReadGeoMatrices()
1539{
b4a9cd27 1540 //
afb9f880 1541 // Read the geo matrices from the current gGeoManager for each TRD detector
1542 //
1543 // This fill three arrays of TGeoHMatrix, ordered by detector numbers
1544 // for fast access:
1545 // fMatrixArray: Used for transformation local <-> global ???
1546 // fMatrixCorrectionArray: Used for transformation local <-> tracking system
1547 // fMatrixGeo: Alignable objects
b4a9cd27 1548 //
1549
030b4415 1550 if (!gGeoManager) {
1551 return kFALSE;
1552 }
0a5f3331 1553
030b4415 1554 fMatrixArray = new TObjArray(kNdet);
b4a9cd27 1555 fMatrixCorrectionArray = new TObjArray(kNdet);
030b4415 1556 fMatrixGeo = new TObjArray(kNdet);
bd0f8685 1557
b4a9cd27 1558 for (Int_t iLayer = AliAlignObj::kTRD1; iLayer <= AliAlignObj::kTRD6; iLayer++) {
1559 for (Int_t iModule = 0; iModule < AliAlignObj::LayerSize(iLayer); iModule++) {
030b4415 1560
afb9f880 1561 // Find the path to the different alignable objects (ROCs)
0a5f3331 1562 UShort_t volid = AliAlignObj::LayerToVolUID(iLayer,iModule);
1563 const char *symname = AliAlignObj::SymName(volid);
1564 TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(symname);
1565 const char *path = symname;
1566 if (pne) {
1567 path = pne->GetTitle();
1568 }
1569 if (!gGeoManager->cd(path)) {
1570 return kFALSE;
1571 }
afb9f880 1572
1573 // Get the geo matrix of the current alignable object
1574 // and add it to the corresponding list
1575 TGeoHMatrix *matrix = gGeoManager->GetCurrentMatrix();
1576 Int_t iplane = iLayer - AliAlignObj::kTRD1;
1577 Int_t isector = iModule / Ncham();
1578 Int_t ichamber = iModule % Ncham();
1579 Int_t idet = GetDetector(iplane,ichamber,isector);
1580 fMatrixGeo->AddAt(new TGeoHMatrix(* matrix),idet);
1581
1582 // Construct the geo matrix for the local <-> global transformation
1583 // and add it to the corresponding list.
1584 // In addition to the original geo matrix also a rotation of the
1585 // kind z-x-y to x-y--z is applied.
1586 TGeoRotation rotMatrixA;
1587 rotMatrixA.RotateY(90);
1588 rotMatrixA.RotateX(90);
1589 TGeoHMatrix matrixGlobal(rotMatrixA.Inverse());
1590 matrixGlobal.MultiplyLeft(matrix);
1591 fMatrixArray->AddAt(new TGeoHMatrix(matrixGlobal),idet);
1592
1593 // Construct the geo matrix for the cluster transformation
1594 // and add it to the corresponding list.
1595 // In addition to the original geo matrix also a rotation of the
1596 // kind x-y--z to z-x-y and a rotation by the sector angle is applied.
030b4415 1597 Double_t sectorAngle = 20.0 * (isector % 18) + 10.0;
afb9f880 1598 TGeoHMatrix rotMatrixB(rotMatrixA.Inverse());
1599 rotMatrixB.MultiplyLeft(matrix);
1600 TGeoHMatrix rotSector;
b4a9cd27 1601 rotSector.RotateZ(sectorAngle);
afb9f880 1602 rotMatrixB.MultiplyLeft(&rotSector);
1603 fMatrixCorrectionArray->AddAt(new TGeoHMatrix(rotMatrixB),idet);
bd0f8685 1604
b4a9cd27 1605 }
1606 }
bd0f8685 1607
b4a9cd27 1608 return kTRUE;
b4a9cd27 1609
bd0f8685 1610}
b4a9cd27 1611