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 ///////////////////////////////////////////////////////////////////////////////
20 // TRD geometry class //
22 ///////////////////////////////////////////////////////////////////////////////
24 #include <TGeoManager.h>
25 #include <TGeoPhysicalNode.h>
26 #include <TVirtualMC.h>
30 #include "AliAlignObjParams.h"
32 #include "AliTRDgeometry.h"
33 #include "AliTRDpadPlane.h"
35 ClassImp(AliTRDgeometry)
37 //_____________________________________________________________________________
40 // The geometry constants
42 const Int_t AliTRDgeometry::fgkNsector = kNsector;
43 const Int_t AliTRDgeometry::fgkNlayer = kNlayer;
44 const Int_t AliTRDgeometry::fgkNstack = kNstack;
45 const Int_t AliTRDgeometry::fgkNdet = kNdet;
48 // Dimensions of the detector
51 // Total length of the TRD mother volume
52 const Float_t AliTRDgeometry::fgkTlength = 751.0;
54 // Parameter of the super module mother volumes
55 const Float_t AliTRDgeometry::fgkSheight = 77.9;
56 const Float_t AliTRDgeometry::fgkSwidth1 = 94.881;
57 const Float_t AliTRDgeometry::fgkSwidth2 = 122.353;
58 const Float_t AliTRDgeometry::fgkSlength = 702.0;
60 // Length of the additional space in front of the supermodule
62 const Float_t AliTRDgeometry::fgkFlength = (AliTRDgeometry::fgkTlength
63 - AliTRDgeometry::fgkSlength) / 2.0;
65 // The super module side plates
66 const Float_t AliTRDgeometry::fgkSMpltT = 0.2;
68 // Vertical spacing of the chambers
69 const Float_t AliTRDgeometry::fgkVspace = 1.784;
70 // Horizontal spacing of the chambers
71 const Float_t AliTRDgeometry::fgkHspace = 2.0;
72 // Radial distance of the first ROC to the outer plates of the SM
73 const Float_t AliTRDgeometry::fgkVrocsm = 1.2;
75 // Height of different chamber parts
77 const Float_t AliTRDgeometry::fgkCraH = 4.8;
79 const Float_t AliTRDgeometry::fgkCdrH = 3.0;
80 // Amplification region
81 const Float_t AliTRDgeometry::fgkCamH = 0.7;
83 const Float_t AliTRDgeometry::fgkCroH = 2.316;
84 // Additional width of the readout chamber frames
85 const Float_t AliTRDgeometry::fgkCroW = 0.9;
86 // Services on top of ROC
87 const Float_t AliTRDgeometry::fgkCsvH = AliTRDgeometry::fgkVspace
89 // Total height (w/o services)
90 const Float_t AliTRDgeometry::fgkCH = AliTRDgeometry::fgkCraH
91 + AliTRDgeometry::fgkCdrH
92 + AliTRDgeometry::fgkCamH
93 + AliTRDgeometry::fgkCroH;
94 // Total height (with services)
96 const Float_t AliTRDgeometry::fgkCHsv = AliTRDgeometry::fgkCH
97 + AliTRDgeometry::fgkCsvH;
99 // Distance of anode wire plane relative to middle of alignable volume
100 const Float_t AliTRDgeometry::fgkAnodePos = AliTRDgeometry::fgkCraH
101 + AliTRDgeometry::fgkCdrH
102 + AliTRDgeometry::fgkCamH/2.0
103 - AliTRDgeometry::fgkCHsv/2.0;
105 // Thicknesses of different parts of the chamber frame
106 // Lower aluminum frame
107 const Float_t AliTRDgeometry::fgkCalT = 0.4;
108 // Lower Wacosit frame sides
109 const Float_t AliTRDgeometry::fgkCclsT = 0.21;
110 // Lower Wacosit frame front
111 const Float_t AliTRDgeometry::fgkCclfT = 1.0;
112 // Thickness of glue around radiator
113 const Float_t AliTRDgeometry::fgkCglT = 0.25;
114 // Upper Wacosit frame around amplification region
115 const Float_t AliTRDgeometry::fgkCcuTa = 1.0;
116 const Float_t AliTRDgeometry::fgkCcuTb = 0.8;
117 // Al frame of back panel
118 const Float_t AliTRDgeometry::fgkCauT = 1.5;
119 // Additional Al ledge at the lower chamber frame
120 // Actually the dimensions are not realistic, but
121 // modified in order to allow to mis-alignment.
122 // The amount of material is, however, correct
123 const Float_t AliTRDgeometry::fgkCalW = 2.5;
124 const Float_t AliTRDgeometry::fgkCalH = 0.4;
125 const Float_t AliTRDgeometry::fgkCalWmod = 0.4;
126 const Float_t AliTRDgeometry::fgkCalHmod = 2.5;
127 // Additional Wacosit ledge at the lower chamber frame
128 const Float_t AliTRDgeometry::fgkCwsW = 1.2;
129 const Float_t AliTRDgeometry::fgkCwsH = 0.3;
131 // Difference of outer chamber width and pad plane width
132 const Float_t AliTRDgeometry::fgkCpadW = 0.0;
133 const Float_t AliTRDgeometry::fgkRpadW = 1.0;
136 // Thickness of the the material layers
138 const Float_t AliTRDgeometry::fgkDrThick = AliTRDgeometry::fgkCdrH;
139 const Float_t AliTRDgeometry::fgkAmThick = AliTRDgeometry::fgkCamH;
140 const Float_t AliTRDgeometry::fgkXeThick = AliTRDgeometry::fgkDrThick
141 + AliTRDgeometry::fgkAmThick;
142 const Float_t AliTRDgeometry::fgkWrThick = 0.00011;
144 const Float_t AliTRDgeometry::fgkRMyThick = 0.0015;
145 const Float_t AliTRDgeometry::fgkRCbThick = 0.0055;
146 const Float_t AliTRDgeometry::fgkRGlThick = 0.0065;
147 const Float_t AliTRDgeometry::fgkRRhThick = 0.8;
148 const Float_t AliTRDgeometry::fgkRFbThick = fgkCraH - 2.0 * (fgkRMyThick
152 const Float_t AliTRDgeometry::fgkPPdThick = 0.0025;
153 const Float_t AliTRDgeometry::fgkPPpThick = 0.0356;
154 const Float_t AliTRDgeometry::fgkPGlThick = 0.1428;
155 const Float_t AliTRDgeometry::fgkPCbThick = 0.019;
156 const Float_t AliTRDgeometry::fgkPPcThick = 0.0486;
157 const Float_t AliTRDgeometry::fgkPRbThick = 0.0057;
158 const Float_t AliTRDgeometry::fgkPElThick = 0.0029;
159 const Float_t AliTRDgeometry::fgkPHcThick = fgkCroH - fgkPPdThick
168 // Position of the material layers
170 const Float_t AliTRDgeometry::fgkDrZpos = 2.4;
171 const Float_t AliTRDgeometry::fgkAmZpos = 0.0;
172 const Float_t AliTRDgeometry::fgkWrZposA = 0.0;
173 const Float_t AliTRDgeometry::fgkWrZposB = -fgkAmThick/2.0 + 0.001;
174 const Float_t AliTRDgeometry::fgkCalZpos = 0.3;
176 const Int_t AliTRDgeometry::fgkMCMmax = 16;
177 const Int_t AliTRDgeometry::fgkMCMrow = 4;
178 const Int_t AliTRDgeometry::fgkROBmaxC0 = 6;
179 const Int_t AliTRDgeometry::fgkROBmaxC1 = 8;
180 const Int_t AliTRDgeometry::fgkADCmax = 21;
181 const Int_t AliTRDgeometry::fgkTBmax = 60;
182 const Int_t AliTRDgeometry::fgkPadmax = 18;
183 const Int_t AliTRDgeometry::fgkColmax = 144;
184 const Int_t AliTRDgeometry::fgkRowmaxC0 = 12;
185 const Int_t AliTRDgeometry::fgkRowmaxC1 = 16;
187 const Double_t AliTRDgeometry::fgkTime0Base = 300.65;
188 const Float_t AliTRDgeometry::fgkTime0[6] = { fgkTime0Base + 0 * (Cheight() + Cspace())
189 , fgkTime0Base + 1 * (Cheight() + Cspace())
190 , fgkTime0Base + 2 * (Cheight() + Cspace())
191 , fgkTime0Base + 3 * (Cheight() + Cspace())
192 , fgkTime0Base + 4 * (Cheight() + Cspace())
193 , fgkTime0Base + 5 * (Cheight() + Cspace())};
195 const Double_t AliTRDgeometry::fgkXtrdBeg = 288.43; // Values depend on position of TRD
196 const Double_t AliTRDgeometry::fgkXtrdEnd = 366.33; // mother volume inside space frame !!!
198 // The outer width of the chambers
199 const Float_t AliTRDgeometry::fgkCwidth[kNlayer] = { 90.4, 94.8, 99.3, 103.7, 108.1, 112.6 };
201 // The outer lengths of the chambers
202 // Includes the spacings between the chambers!
203 const Float_t AliTRDgeometry::fgkClength[kNlayer][kNstack] = { { 124.0, 124.0, 110.0, 124.0, 124.0 }
204 , { 124.0, 124.0, 110.0, 124.0, 124.0 }
205 , { 131.0, 131.0, 110.0, 131.0, 131.0 }
206 , { 138.0, 138.0, 110.0, 138.0, 138.0 }
207 , { 145.0, 145.0, 110.0, 145.0, 145.0 }
208 , { 147.0, 147.0, 110.0, 147.0, 147.0 } };
210 Char_t AliTRDgeometry::fgSMstatus[kNsector] = { 1, 1, 1, 1, 1, 1, 1, 1, 1
211 , 1, 1, 1, 1, 1, 1, 1, 1, 1 };
213 TObjArray* AliTRDgeometry::fgClusterMatrixArray = NULL;
215 TObjArray* AliTRDgeometry::fgPadPlaneArray = NULL;
217 //_____________________________________________________________________________
218 AliTRDgeometry::AliTRDgeometry()
221 // AliTRDgeometry default constructor
226 //_____________________________________________________________________________
227 AliTRDgeometry::~AliTRDgeometry()
230 // AliTRDgeometry destructor
235 //_____________________________________________________________________________
236 void AliTRDgeometry::CreatePadPlaneArray()
239 // Creates the array of AliTRDpadPlane objects
245 fgPadPlaneArray = new TObjArray(fgkNlayer * fgkNstack);
246 for (Int_t ilayer = 0; ilayer < fgkNlayer; ilayer++) {
247 for (Int_t istack = 0; istack < fgkNstack; istack++) {
248 Int_t ipp = GetDetectorSec(ilayer,istack);
249 fgPadPlaneArray->AddAt(CreatePadPlane(ilayer,istack),ipp);
255 //_____________________________________________________________________________
256 AliTRDpadPlane *AliTRDgeometry::CreatePadPlane(Int_t ilayer, Int_t istack)
259 // Creates an AliTRDpadPlane object
262 AliTRDpadPlane *padPlane = new AliTRDpadPlane();
264 padPlane->SetLayer(ilayer);
265 padPlane->SetStack(istack);
267 padPlane->SetRowSpacing(0.0);
268 padPlane->SetColSpacing(0.0);
270 padPlane->SetLengthRim(1.0);
271 padPlane->SetWidthRim(0.5);
273 padPlane->SetNcols(144);
275 padPlane->SetAnodeWireOffset(0.25);
278 // The pad plane parameter
280 const Float_t kTiltAngle = 2.0;
285 padPlane->SetNrows(12);
286 padPlane->SetLength(108.0);
287 padPlane->SetLengthOPad(8.0);
288 padPlane->SetLengthIPad(9.0);
292 padPlane->SetNrows(16);
293 padPlane->SetLength(122.0);
294 padPlane->SetLengthOPad(7.5);
295 padPlane->SetLengthIPad(7.5);
297 padPlane->SetWidth(92.2);
298 padPlane->SetWidthOPad(0.515);
299 padPlane->SetWidthIPad(0.635);
300 padPlane->SetTiltingAngle(-kTiltAngle);
305 padPlane->SetNrows(12);
306 padPlane->SetLength(108.0);
307 padPlane->SetLengthOPad(8.0);
308 padPlane->SetLengthIPad(9.0);
312 padPlane->SetNrows(16);
313 padPlane->SetLength(122.0);
314 padPlane->SetLengthOPad(7.5);
315 padPlane->SetLengthIPad(7.5);
317 padPlane->SetWidth(96.6);
318 padPlane->SetWidthOPad(0.585);
319 padPlane->SetWidthIPad(0.665);
320 padPlane->SetTiltingAngle(kTiltAngle);
325 padPlane->SetNrows(12);
326 padPlane->SetLength(108.0);
327 padPlane->SetLengthOPad(8.0);
328 padPlane->SetLengthIPad(9.0);
332 padPlane->SetNrows(16);
333 padPlane->SetLength(129.0);
334 padPlane->SetLengthOPad(7.5);
335 padPlane->SetLengthIPad(8.0);
337 padPlane->SetWidth(101.1);
338 padPlane->SetWidthOPad(0.705);
339 padPlane->SetWidthIPad(0.695);
340 padPlane->SetTiltingAngle(-kTiltAngle);
345 padPlane->SetNrows(12);
346 padPlane->SetLength(108.0);
347 padPlane->SetLengthOPad(8.0);
348 padPlane->SetLengthIPad(9.0);
352 padPlane->SetNrows(16);
353 padPlane->SetLength(136.0);
354 padPlane->SetLengthOPad(7.5);
355 padPlane->SetLengthIPad(8.5);
357 padPlane->SetWidth(105.5);
358 padPlane->SetWidthOPad(0.775);
359 padPlane->SetWidthIPad(0.725);
360 padPlane->SetTiltingAngle(kTiltAngle);
365 padPlane->SetNrows(12);
366 padPlane->SetLength(108.0);
367 padPlane->SetLengthOPad(8.0);
371 padPlane->SetNrows(16);
372 padPlane->SetLength(143.0);
373 padPlane->SetLengthOPad(7.5);
375 padPlane->SetWidth(109.9);
376 padPlane->SetWidthOPad(0.845);
377 padPlane->SetLengthIPad(9.0);
378 padPlane->SetWidthIPad(0.755);
379 padPlane->SetTiltingAngle(-kTiltAngle);
384 padPlane->SetNrows(12);
385 padPlane->SetLength(108.0);
386 padPlane->SetLengthOPad(8.0);
390 padPlane->SetNrows(16);
391 padPlane->SetLength(145.0);
392 padPlane->SetLengthOPad(8.5);
394 padPlane->SetWidth(114.4);
395 padPlane->SetWidthOPad(0.965);
396 padPlane->SetLengthIPad(9.0);
397 padPlane->SetWidthIPad(0.785);
398 padPlane->SetTiltingAngle(kTiltAngle);
403 // The positions of the borders of the pads
407 Double_t row = fgkClength[ilayer][istack] / 2.0
409 - padPlane->GetLengthRim();
410 for (Int_t ir = 0; ir < padPlane->GetNrows(); ir++) {
411 padPlane->SetPadRow(ir,row);
412 row -= padPlane->GetRowSpacing();
414 row -= padPlane->GetLengthOPad();
417 row -= padPlane->GetLengthIPad();
423 Double_t col = - fgkCwidth[ilayer] / 2.0
425 + padPlane->GetWidthRim();
426 for (Int_t ic = 0; ic < padPlane->GetNcols(); ic++) {
427 padPlane->SetPadCol(ic,col);
428 col += padPlane->GetColSpacing();
430 col += padPlane->GetWidthOPad();
433 col += padPlane->GetWidthIPad();
436 // Calculate the offset to translate from the local ROC system into
437 // the local supermodule system, which is used for clusters
438 Double_t rowTmp = fgkClength[ilayer][0]
439 + fgkClength[ilayer][1]
440 + fgkClength[ilayer][2] / 2.0;
441 for (Int_t jstack = 0; jstack < istack; jstack++) {
442 rowTmp -= fgkClength[ilayer][jstack];
444 padPlane->SetPadRowSMOffset(rowTmp - fgkClength[ilayer][istack]/2.0);
450 //_____________________________________________________________________________
451 void AliTRDgeometry::CreateGeometry(Int_t *idtmed)
454 // Create the TRD geometry
457 // Names of the TRD volumina (xx = detector number):
459 // Volume (Air) wrapping the readout chamber components
460 // UTxx includes: UAxx, UDxx, UFxx, UUxx
462 // Lower part of the readout chambers (drift volume + radiator)
463 // UAxx Aluminum frames (Al)
465 // Upper part of the readout chambers (readout plane + fee)
466 // UDxx Wacosit frames of amp. region (Wacosit)
467 // UFxx Aluminum frame of back panel (Al)
469 // Services on chambers (cooling, cables, MCMs, DCS boards, ...)
470 // UUxx Volume containing the services (Air)
472 // Material layers inside sensitive area:
473 // Name Description Mat. Thick. Dens. Radl. X/X_0
475 // URMYxx Mylar layers (x2) Mylar 0.0015 1.39 28.5464 0.005%
476 // URCBxx Carbon layer (x2) Carbon 0.0055 1.75 24.2824 0.023%
477 // URGLxx Glue on the carbon layers (x2) Araldite 0.0065 1.12 37.0664 0.018%
478 // URRHxx Rohacell layer (x2) Rohacell 0.8 0.075 536.005 0.149%
479 // URFBxx Fiber mat layer PP 3.186 0.068 649.727 0.490%
481 // UJxx Drift region Xe/CO2 3.0 0.00495 1792.37 0.167%
482 // UKxx Amplification region Xe/CO2 0.7 0.00495 1792.37 0.039%
483 // UWxx Wire planes (x2) Copper 0.00011 8.96 1.43503 0.008%
485 // UPPDxx Copper of pad plane Copper 0.0025 8.96 1.43503 0.174%
486 // UPPPxx PCB of pad plane G10 0.0356 2.0 14.9013 0.239%
487 // UPGLxx Glue on pad planes Araldite 0.0923 1.12 37.0664 0.249%
488 // + add. glue (ca. 600g) Araldite 0.0505 1.12 37.0663 0.107%
489 // UPCBxx Carbon fiber mats (x2) Carbon 0.019 1.75 24.2824 0.078%
490 // UPHCxx Honeycomb structure Aramide 2.0299 0.032 1198.84 0.169%
491 // UPPCxx PCB of readout board G10 0.0486 2.0 14.9013 0.326%
492 // UPRDxx Copper of readout board Copper 0.0057 8.96 1.43503 0.404%
493 // UPELxx Electronics + cables Copper 0.0029 8.96 1.43503 0.202%
496 const Int_t kNparTrd = 4;
497 const Int_t kNparCha = 3;
503 Float_t parTrd[kNparTrd];
504 Float_t parCha[kNparCha];
506 const Int_t kTag = 100;
510 // There are three TRD volumes for the supermodules in order to accomodate
511 // the different arrangements in front of PHOS
512 // UTR1: Default supermodule
513 // UTR2: Supermodule in front of PHOS with double carbon cover
514 // UTR3: As UTR2, but w/o middle stack
516 // The mother volume for one sector (Air), full length in z-direction
517 // Provides material for side plates of super module
518 parTrd[0] = fgkSwidth1/2.0;
519 parTrd[1] = fgkSwidth2/2.0;
520 parTrd[2] = fgkSlength/2.0;
521 parTrd[3] = fgkSheight/2.0;
522 gMC->Gsvolu("UTR1","TRD1",idtmed[1302-1],parTrd,kNparTrd);
523 gMC->Gsvolu("UTR2","TRD1",idtmed[1302-1],parTrd,kNparTrd);
524 gMC->Gsvolu("UTR3","TRD1",idtmed[1302-1],parTrd,kNparTrd);
525 // The outer aluminum plates of the super module (Al)
526 parTrd[0] = fgkSwidth1/2.0;
527 parTrd[1] = fgkSwidth2/2.0;
528 parTrd[2] = fgkSlength/2.0;
529 parTrd[3] = fgkSheight/2.0;
530 gMC->Gsvolu("UTS1","TRD1",idtmed[1301-1],parTrd,kNparTrd);
531 gMC->Gsvolu("UTS2","TRD1",idtmed[1301-1],parTrd,kNparTrd);
532 gMC->Gsvolu("UTS3","TRD1",idtmed[1301-1],parTrd,kNparTrd);
533 // The inner part of the TRD mother volume for one sector (Air),
534 // full length in z-direction
535 parTrd[0] = fgkSwidth1/2.0 - fgkSMpltT;
536 parTrd[1] = fgkSwidth2/2.0 - fgkSMpltT;
537 parTrd[2] = fgkSlength/2.0;
538 parTrd[3] = fgkSheight/2.0 - fgkSMpltT;
539 gMC->Gsvolu("UTI1","TRD1",idtmed[1302-1],parTrd,kNparTrd);
540 gMC->Gsvolu("UTI2","TRD1",idtmed[1302-1],parTrd,kNparTrd);
541 gMC->Gsvolu("UTI3","TRD1",idtmed[1302-1],parTrd,kNparTrd);
543 // The inner part of the TRD mother volume for services in front
544 // of the supermodules (Air),
545 parTrd[0] = fgkSwidth1/2.0;
546 parTrd[1] = fgkSwidth2/2.0;
547 parTrd[2] = fgkFlength/2.0;
548 parTrd[3] = fgkSheight/2.0;
549 gMC->Gsvolu("UTF1","TRD1",idtmed[1302-1],parTrd,kNparTrd);
550 gMC->Gsvolu("UTF2","TRD1",idtmed[1302-1],parTrd,kNparTrd);
552 for (Int_t istack = 0; istack < kNstack; istack++) {
553 for (Int_t ilayer = 0; ilayer < kNlayer; ilayer++) {
555 Int_t iDet = GetDetectorSec(ilayer,istack);
557 // The lower part of the readout chambers (drift volume + radiator)
558 // The aluminum frames
559 snprintf(cTagV,kTag,"UA%02d",iDet);
560 parCha[0] = fgkCwidth[ilayer]/2.0;
561 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
562 parCha[2] = fgkCraH/2.0 + fgkCdrH/2.0;
563 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
564 // The additional aluminum on the frames
565 // This part has not the correct shape but is just supposed to
566 // represent the missing material. The correct form of the L-shaped
567 // profile would not fit into the alignable volume.
568 snprintf(cTagV,kTag,"UZ%02d",iDet);
569 parCha[0] = fgkCalWmod/2.0;
570 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
571 parCha[2] = fgkCalHmod/2.0;
572 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
573 // The additional Wacosit on the frames
574 snprintf(cTagV,kTag,"UP%02d",iDet);
575 parCha[0] = fgkCwsW/2.0;
576 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
577 parCha[2] = fgkCwsH/2.0;
578 gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
579 // The Wacosit frames
580 snprintf(cTagV,kTag,"UB%02d",iDet);
581 parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT;
584 gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
585 // The glue around the radiator
586 snprintf(cTagV,kTag,"UX%02d",iDet);
587 parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT;
588 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT;
589 parCha[2] = fgkCraH/2.0;
590 gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
591 // The inner part of radiator (air)
592 snprintf(cTagV,kTag,"UC%02d",iDet);
593 parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT - fgkCglT;
594 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT - fgkCglT;
596 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
598 // The upper part of the readout chambers (amplification volume)
599 // The Wacosit frames
600 snprintf(cTagV,kTag,"UD%02d",iDet);
601 parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW;
602 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
603 parCha[2] = fgkCamH/2.0;
604 gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
605 // The inner part of the Wacosit frame (air)
606 snprintf(cTagV,kTag,"UE%02d",iDet);
607 parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW - fgkCcuTb;
608 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCcuTa;
610 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
612 // The back panel, including pad plane and readout boards
613 // The aluminum frames
614 snprintf(cTagV,kTag,"UF%02d",iDet);
615 parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW;
616 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
617 parCha[2] = fgkCroH/2.0;
618 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
619 // The inner part of the aluminum frames
620 snprintf(cTagV,kTag,"UG%02d",iDet);
621 parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW - fgkCauT;
622 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCauT;
624 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parCha,kNparCha);
627 // The material layers inside the chambers
630 // Mylar layer (radiator)
633 parCha[2] = fgkRMyThick/2.0;
634 snprintf(cTagV,kTag,"URMY%02d",iDet);
635 gMC->Gsvolu(cTagV,"BOX ",idtmed[1327-1],parCha,kNparCha);
636 // Carbon layer (radiator)
639 parCha[2] = fgkRCbThick/2.0;
640 snprintf(cTagV,kTag,"URCB%02d",iDet);
641 gMC->Gsvolu(cTagV,"BOX ",idtmed[1326-1],parCha,kNparCha);
642 // Araldite layer (radiator)
645 parCha[2] = fgkRGlThick/2.0;
646 snprintf(cTagV,kTag,"URGL%02d",iDet);
647 gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
648 // Rohacell layer (radiator)
651 parCha[2] = fgkRRhThick/2.0;
652 snprintf(cTagV,kTag,"URRH%02d",iDet);
653 gMC->Gsvolu(cTagV,"BOX ",idtmed[1315-1],parCha,kNparCha);
654 // Fiber layer (radiator)
657 parCha[2] = fgkRFbThick/2.0;
658 snprintf(cTagV,kTag,"URFB%02d",iDet);
659 gMC->Gsvolu(cTagV,"BOX ",idtmed[1328-1],parCha,kNparCha);
661 // Xe/Isobutane layer (drift volume)
662 parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT;
663 parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT;
664 parCha[2] = fgkDrThick/2.0;
665 snprintf(cTagV,kTag,"UJ%02d",iDet);
666 gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
668 // Xe/Isobutane layer (amplification volume)
671 parCha[2] = fgkAmThick/2.0;
672 snprintf(cTagV,kTag,"UK%02d",iDet);
673 gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
674 // Cu layer (wire plane)
677 parCha[2] = fgkWrThick/2.0;
678 snprintf(cTagV,kTag,"UW%02d",iDet);
679 gMC->Gsvolu(cTagV,"BOX ",idtmed[1303-1],parCha,kNparCha);
681 // Cu layer (pad plane)
684 parCha[2] = fgkPPdThick/2.0;
685 snprintf(cTagV,kTag,"UPPD%02d",iDet);
686 gMC->Gsvolu(cTagV,"BOX ",idtmed[1305-1],parCha,kNparCha);
687 // G10 layer (pad plane)
690 parCha[2] = fgkPPpThick/2.0;
691 snprintf(cTagV,kTag,"UPPP%02d",iDet);
692 gMC->Gsvolu(cTagV,"BOX ",idtmed[1313-1],parCha,kNparCha);
693 // Araldite layer (glue)
696 parCha[2] = fgkPGlThick/2.0;
697 snprintf(cTagV,kTag,"UPGL%02d",iDet);
698 gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
699 // Carbon layer (carbon fiber mats)
702 parCha[2] = fgkPCbThick/2.0;
703 snprintf(cTagV,kTag,"UPCB%02d",iDet);
704 gMC->Gsvolu(cTagV,"BOX ",idtmed[1326-1],parCha,kNparCha);
705 // Aramide layer (honeycomb)
708 parCha[2] = fgkPHcThick/2.0;
709 snprintf(cTagV,kTag,"UPHC%02d",iDet);
710 gMC->Gsvolu(cTagV,"BOX ",idtmed[1310-1],parCha,kNparCha);
711 // G10 layer (PCB readout board)
714 parCha[2] = fgkPPcThick/2;
715 snprintf(cTagV,kTag,"UPPC%02d",iDet);
716 gMC->Gsvolu(cTagV,"BOX ",idtmed[1313-1],parCha,kNparCha);
717 // Cu layer (traces in readout board)
720 parCha[2] = fgkPRbThick/2.0;
721 snprintf(cTagV,kTag,"UPRB%02d",iDet);
722 gMC->Gsvolu(cTagV,"BOX ",idtmed[1306-1],parCha,kNparCha);
723 // Cu layer (other material on in readout board, incl. screws)
726 parCha[2] = fgkPElThick/2.0;
727 snprintf(cTagV,kTag,"UPEL%02d",iDet);
728 gMC->Gsvolu(cTagV,"BOX ",idtmed[1304-1],parCha,kNparCha);
731 // Position the layers in the chambers
737 // Mylar layers (radiator)
738 zpos = fgkRMyThick/2.0 - fgkCraH/2.0;
739 snprintf(cTagV,kTag,"URMY%02d",iDet);
740 snprintf(cTagM,kTag,"UC%02d",iDet);
741 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
742 zpos = -fgkRMyThick/2.0 + fgkCraH/2.0;
743 snprintf(cTagV,kTag,"URMY%02d",iDet);
744 snprintf(cTagM,kTag,"UC%02d",iDet);
745 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
746 // Carbon layers (radiator)
747 zpos = fgkRCbThick/2.0 + fgkRMyThick - fgkCraH/2.0;
748 snprintf(cTagV,kTag,"URCB%02d",iDet);
749 snprintf(cTagM,kTag,"UC%02d",iDet);
750 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
751 zpos = -fgkRCbThick/2.0 - fgkRMyThick + fgkCraH/2.0;
752 snprintf(cTagV,kTag,"URCB%02d",iDet);
753 snprintf(cTagM,kTag,"UC%02d",iDet);
754 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
755 // Carbon layers (radiator)
756 zpos = fgkRGlThick/2.0 + fgkRCbThick + fgkRMyThick - fgkCraH/2.0;
757 snprintf(cTagV,kTag,"URGL%02d",iDet);
758 snprintf(cTagM,kTag,"UC%02d",iDet);
759 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
760 zpos = -fgkRGlThick/2.0 - fgkRCbThick - fgkRMyThick + fgkCraH/2.0;
761 snprintf(cTagV,kTag,"URGL%02d",iDet);
762 snprintf(cTagM,kTag,"UC%02d",iDet);
763 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
764 // Rohacell layers (radiator)
765 zpos = fgkRRhThick/2.0 + fgkRGlThick + fgkRCbThick + fgkRMyThick - fgkCraH/2.0;
766 snprintf(cTagV,kTag,"URRH%02d",iDet);
767 snprintf(cTagM,kTag,"UC%02d",iDet);
768 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
769 zpos = -fgkRRhThick/2.0 - fgkRGlThick - fgkRCbThick - fgkRMyThick + fgkCraH/2.0;
770 snprintf(cTagV,kTag,"URRH%02d",iDet);
771 snprintf(cTagM,kTag,"UC%02d",iDet);
772 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
773 // Fiber layers (radiator)
775 snprintf(cTagV,kTag,"URFB%02d",iDet);
776 snprintf(cTagM,kTag,"UC%02d",iDet);
777 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
779 // Xe/Isobutane layer (drift volume)
781 snprintf(cTagV,kTag,"UJ%02d",iDet);
782 snprintf(cTagM,kTag,"UB%02d",iDet);
783 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
786 // Xe/Isobutane layer (amplification volume)
788 snprintf(cTagV,kTag,"UK%02d",iDet);
789 snprintf(cTagM,kTag,"UE%02d",iDet);
790 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
791 // Cu layer (wire planes inside amplification volume)
793 snprintf(cTagV,kTag,"UW%02d",iDet);
794 snprintf(cTagM,kTag,"UK%02d",iDet);
795 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
797 snprintf(cTagV,kTag,"UW%02d",iDet);
798 snprintf(cTagM,kTag,"UK%02d",iDet);
799 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
801 // Back panel + pad plane + readout part
802 // Cu layer (pad plane)
803 zpos = fgkPPdThick/2.0 - fgkCroH/2.0;
804 snprintf(cTagV,kTag,"UPPD%02d",iDet);
805 snprintf(cTagM,kTag,"UG%02d",iDet);
806 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
807 // G10 layer (pad plane)
808 zpos = fgkPPpThick/2.0 + fgkPPdThick - fgkCroH/2.0;
809 snprintf(cTagV,kTag,"UPPP%02d",iDet);
810 snprintf(cTagM,kTag,"UG%02d",iDet);
811 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
812 // Araldite layer (glue)
813 zpos = fgkPGlThick/2.0 + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
814 snprintf(cTagV,kTag,"UPGL%02d",iDet);
815 snprintf(cTagM,kTag,"UG%02d",iDet);
816 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
817 // Carbon layers (carbon fiber mats)
818 zpos = fgkPCbThick/2.0 + fgkPGlThick + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
819 snprintf(cTagV,kTag,"UPCB%02d",iDet);
820 snprintf(cTagM,kTag,"UG%02d",iDet);
821 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
822 zpos = -fgkPCbThick/2.0 - fgkPPcThick - fgkPRbThick - fgkPElThick + fgkCroH/2.0;
823 snprintf(cTagV,kTag,"UPCB%02d",iDet);
824 snprintf(cTagM,kTag,"UG%02d",iDet);
825 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
826 // Aramide layer (honeycomb)
827 zpos = fgkPHcThick/2.0 + fgkPCbThick + fgkPGlThick + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
828 snprintf(cTagV,kTag,"UPHC%02d",iDet);
829 snprintf(cTagM,kTag,"UG%02d",iDet);
830 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
831 // G10 layer (PCB readout board)
832 zpos = -fgkPPcThick/2.0 - fgkPRbThick - fgkPElThick + fgkCroH/2.0;
833 snprintf(cTagV,kTag,"UPPC%02d",iDet);
834 snprintf(cTagM,kTag,"UG%02d",iDet);
835 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
836 // Cu layer (traces in readout board)
837 zpos = -fgkPRbThick/2.0 - fgkPElThick + fgkCroH/2.0;
838 snprintf(cTagV,kTag,"UPRB%02d",iDet);
839 snprintf(cTagM,kTag,"UG%02d",iDet);
840 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
841 // Cu layer (other materials on readout board, incl. screws)
842 zpos = -fgkPElThick/2.0 + fgkCroH/2.0;
843 snprintf(cTagV,kTag,"UPEL%02d",iDet);
844 snprintf(cTagM,kTag,"UG%02d",iDet);
845 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
847 // Position the inner volumes of the chambers in the frames
851 // The inner part of the radiator (air)
853 snprintf(cTagV,kTag,"UC%02d",iDet);
854 snprintf(cTagM,kTag,"UX%02d",iDet);
855 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
856 // The glue around the radiator
857 zpos = fgkCraH/2.0 - fgkCdrH/2.0 - fgkCraH/2.0;
858 snprintf(cTagV,kTag,"UX%02d",iDet);
859 snprintf(cTagM,kTag,"UB%02d",iDet);
860 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
861 // The lower Wacosit frame inside the aluminum frame
863 snprintf(cTagV,kTag,"UB%02d",iDet);
864 snprintf(cTagM,kTag,"UA%02d",iDet);
865 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
867 // The inside of the upper Wacosit frame
869 snprintf(cTagV,kTag,"UE%02d",iDet);
870 snprintf(cTagM,kTag,"UD%02d",iDet);
871 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
873 // The inside of the upper aluminum frame
875 snprintf(cTagV,kTag,"UG%02d",iDet);
876 snprintf(cTagM,kTag,"UF%02d",iDet);
877 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
882 // Create the volumes of the super module frame
885 // Create the volumes of the services
886 CreateServices(idtmed);
888 for (Int_t istack = 0; istack < kNstack; istack++) {
889 for (Int_t ilayer = 0; ilayer < kNlayer; ilayer++) {
890 AssembleChamber(ilayer,istack);
897 gMC->Gspos("UTI1",1,"UTS1",xpos,ypos,zpos,0,"ONLY");
898 gMC->Gspos("UTI2",1,"UTS2",xpos,ypos,zpos,0,"ONLY");
899 gMC->Gspos("UTI3",1,"UTS3",xpos,ypos,zpos,0,"ONLY");
904 gMC->Gspos("UTS1",1,"UTR1",xpos,ypos,zpos,0,"ONLY");
905 gMC->Gspos("UTS2",1,"UTR2",xpos,ypos,zpos,0,"ONLY");
906 gMC->Gspos("UTS3",1,"UTR3",xpos,ypos,zpos,0,"ONLY");
908 // Put the TRD volumes into the space frame mother volumes
909 // if enabled via status flag
913 for (Int_t isector = 0; isector < kNsector; isector++) {
914 if (GetSMstatus(isector)) {
915 snprintf(cTagV,kTag,"BTRD%d",isector);
920 // Double carbon, w/o middle stack
921 gMC->Gspos("UTR3",1,cTagV,xpos,ypos,zpos,0,"ONLY");
925 // Double carbon, all stacks
926 gMC->Gspos("UTR2",1,cTagV,xpos,ypos,zpos,0,"ONLY");
929 // Standard supermodule
930 gMC->Gspos("UTR1",1,cTagV,xpos,ypos,zpos,0,"ONLY");
935 // Put the TRD volumes into the space frame mother volumes
936 // if enabled via status flag
938 ypos = 0.5*fgkSlength + 0.5*fgkFlength;
940 for (Int_t isector = 0; isector < kNsector; isector++) {
941 if (GetSMstatus(isector)) {
942 snprintf(cTagV,kTag,"BTRD%d",isector);
943 gMC->Gspos("UTF1",1,cTagV,xpos, ypos,zpos,0,"ONLY");
944 gMC->Gspos("UTF2",1,cTagV,xpos,-ypos,zpos,0,"ONLY");
950 //_____________________________________________________________________________
951 void AliTRDgeometry::CreateFrame(Int_t *idtmed)
954 // Create the geometry of the frame of the supermodule
956 // Names of the TRD services volumina
958 // USRL Support rails for the chambers (Al)
959 // USxx Support cross bars between the chambers (Al)
960 // USHx Horizontal connection between the cross bars (Al)
961 // USLx Long corner ledges (Al)
970 const Int_t kTag = 100;
974 const Int_t kNparTRD = 4;
975 Float_t parTRD[kNparTRD];
976 const Int_t kNparBOX = 3;
977 Float_t parBOX[kNparBOX];
978 const Int_t kNparTRP = 11;
979 Float_t parTRP[kNparTRP];
981 // The rotation matrices
982 const Int_t kNmatrix = 7;
983 Int_t matrix[kNmatrix];
984 gMC->Matrix(matrix[0], 100.0, 0.0, 90.0, 90.0, 10.0, 0.0);
985 gMC->Matrix(matrix[1], 80.0, 0.0, 90.0, 90.0, 10.0, 180.0);
986 gMC->Matrix(matrix[2], 90.0, 0.0, 0.0, 0.0, 90.0, 90.0);
987 gMC->Matrix(matrix[3], 90.0, 180.0, 0.0, 180.0, 90.0, 90.0);
988 gMC->Matrix(matrix[4], 170.0, 0.0, 80.0, 0.0, 90.0, 90.0);
989 gMC->Matrix(matrix[5], 170.0, 180.0, 80.0, 180.0, 90.0, 90.0);
990 gMC->Matrix(matrix[6], 180.0, 180.0, 90.0, 180.0, 90.0, 90.0);
993 // The carbon inserts in the top/bottom aluminum plates
996 const Int_t kNparCrb = 3;
997 Float_t parCrb[kNparCrb];
1001 gMC->Gsvolu("USCR","BOX ",idtmed[1326-1],parCrb,0);
1002 // Bottom 1 (all sectors)
1003 parCrb[0] = 77.49/2.0;
1004 parCrb[1] = 104.60/2.0;
1005 parCrb[2] = fgkSMpltT/2.0;
1008 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1009 gMC->Gsposp("USCR", 1,"UTS1", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1010 gMC->Gsposp("USCR", 2,"UTS2", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1011 gMC->Gsposp("USCR", 3,"UTS3", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1012 // Bottom 2 (all sectors)
1013 parCrb[0] = 77.49/2.0;
1014 parCrb[1] = 55.80/2.0;
1015 parCrb[2] = fgkSMpltT/2.0;
1018 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1019 gMC->Gsposp("USCR", 4,"UTS1", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1020 gMC->Gsposp("USCR", 5,"UTS2", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1021 gMC->Gsposp("USCR", 6,"UTS3", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1022 gMC->Gsposp("USCR", 7,"UTS1", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1023 gMC->Gsposp("USCR", 8,"UTS2", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1024 gMC->Gsposp("USCR", 9,"UTS3", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1025 // Bottom 3 (all sectors)
1026 parCrb[0] = 77.49/2.0;
1027 parCrb[1] = 56.00/2.0;
1028 parCrb[2] = fgkSMpltT/2.0;
1031 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1032 gMC->Gsposp("USCR",10,"UTS1", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1033 gMC->Gsposp("USCR",11,"UTS2", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1034 gMC->Gsposp("USCR",12,"UTS3", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1035 gMC->Gsposp("USCR",13,"UTS1", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1036 gMC->Gsposp("USCR",14,"UTS2", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1037 gMC->Gsposp("USCR",15,"UTS3", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1038 // Bottom 4 (all sectors)
1039 parCrb[0] = 77.49/2.0;
1040 parCrb[1] = 118.00/2.0;
1041 parCrb[2] = fgkSMpltT/2.0;
1044 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1045 gMC->Gsposp("USCR",16,"UTS1", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1046 gMC->Gsposp("USCR",17,"UTS2", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1047 gMC->Gsposp("USCR",18,"UTS3", xpos, ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1048 gMC->Gsposp("USCR",19,"UTS1", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1049 gMC->Gsposp("USCR",20,"UTS2", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1050 gMC->Gsposp("USCR",21,"UTS3", xpos,-ypos, zpos,0,"ONLY",parCrb,kNparCrb);
1051 // Top 1 (only in front of PHOS)
1052 parCrb[0] = 111.48/2.0;
1053 parCrb[1] = 105.00/2.0;
1054 parCrb[2] = fgkSMpltT/2.0;
1057 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1058 gMC->Gsposp("USCR",22,"UTS2", xpos, ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1059 gMC->Gsposp("USCR",23,"UTS3", xpos, ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1060 // Top 2 (only in front of PHOS)
1061 parCrb[0] = 111.48/2.0;
1062 parCrb[1] = 56.00/2.0;
1063 parCrb[2] = fgkSMpltT/2.0;
1066 zpos = fgkSMpltT/2.0 - fgkSheight/2.0;
1067 gMC->Gsposp("USCR",24,"UTS2", xpos, ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1068 gMC->Gsposp("USCR",25,"UTS3", xpos, ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1069 gMC->Gsposp("USCR",26,"UTS2", xpos,-ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1070 gMC->Gsposp("USCR",27,"UTS3", xpos,-ypos,-zpos,0,"ONLY",parCrb,kNparCrb);
1073 // The chamber support rails
1076 const Float_t kSRLhgt = 2.00;
1077 const Float_t kSRLwidA = 2.3;
1078 const Float_t kSRLwidB = 1.947;
1079 const Float_t kSRLdst = 1.135;
1080 const Int_t kNparSRL = 11;
1081 Float_t parSRL[kNparSRL];
1082 // Trapezoidal shape
1083 parSRL[ 0] = fgkSlength/2.0;
1086 parSRL[ 3] = kSRLhgt /2.0;
1087 parSRL[ 4] = kSRLwidB /2.0;
1088 parSRL[ 5] = kSRLwidA /2.0;
1090 parSRL[ 7] = kSRLhgt /2.0;
1091 parSRL[ 8] = kSRLwidB /2.0;
1092 parSRL[ 9] = kSRLwidA /2.0;
1094 gMC->Gsvolu("USRL","TRAP",idtmed[1301-1],parSRL,kNparSRL);
1099 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1100 xpos = fgkCwidth[ilayer]/2.0 + kSRLwidA/2.0 + kSRLdst;
1102 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos - fgkSheight/2.0
1103 + fgkCraH + fgkCdrH - fgkCalH - kSRLhgt/2.0
1104 + ilayer * (fgkCH + fgkVspace);
1105 gMC->Gspos("USRL",ilayer+1 ,"UTI1", xpos,ypos,zpos,matrix[2],"ONLY");
1106 gMC->Gspos("USRL",ilayer+1+ kNlayer,"UTI1",-xpos,ypos,zpos,matrix[3],"ONLY");
1107 gMC->Gspos("USRL",ilayer+1+2*kNlayer,"UTI2", xpos,ypos,zpos,matrix[2],"ONLY");
1108 gMC->Gspos("USRL",ilayer+1+3*kNlayer,"UTI2",-xpos,ypos,zpos,matrix[3],"ONLY");
1109 gMC->Gspos("USRL",ilayer+1+4*kNlayer,"UTI3", xpos,ypos,zpos,matrix[2],"ONLY");
1110 gMC->Gspos("USRL",ilayer+1+5*kNlayer,"UTI3",-xpos,ypos,zpos,matrix[3],"ONLY");
1114 // The cross bars between the chambers
1117 const Float_t kSCBwid = 1.0;
1118 const Float_t kSCBthk = 2.0;
1119 const Float_t kSCHhgt = 0.3;
1121 const Int_t kNparSCB = 3;
1122 Float_t parSCB[kNparSCB];
1123 parSCB[1] = kSCBwid/2.0;
1124 parSCB[2] = fgkCH /2.0 + fgkVspace/2.0 - kSCHhgt;
1126 const Int_t kNparSCI = 3;
1127 Float_t parSCI[kNparSCI];
1133 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
1135 // The aluminum of the cross bars
1136 parSCB[0] = fgkCwidth[ilayer]/2.0 + kSRLdst/2.0;
1137 snprintf(cTagV,kTag,"USF%01d",ilayer);
1138 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCB,kNparSCB);
1140 // The empty regions in the cross bars
1141 Float_t thkSCB = kSCBthk;
1145 parSCI[2] = parSCB[2] - thkSCB;
1146 parSCI[0] = parSCB[0]/4.0 - kSCBthk;
1147 snprintf(cTagV,kTag,"USI%01d",ilayer);
1148 gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parSCI,kNparSCI);
1150 snprintf(cTagV,kTag,"USI%01d",ilayer);
1151 snprintf(cTagM,kTag,"USF%01d",ilayer);
1154 xpos = parSCI[0] + thkSCB/2.0;
1155 gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
1156 xpos = - parSCI[0] - thkSCB/2.0;
1157 gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
1158 xpos = 3.0 * parSCI[0] + 1.5 * thkSCB;
1159 gMC->Gspos(cTagV,3,cTagM,xpos,ypos,zpos,0,"ONLY");
1160 xpos = - 3.0 * parSCI[0] - 1.5 * thkSCB;
1161 gMC->Gspos(cTagV,4,cTagM,xpos,ypos,zpos,0,"ONLY");
1163 snprintf(cTagV,kTag,"USF%01d",ilayer);
1165 zpos = fgkVrocsm + fgkSMpltT + parSCB[2] - fgkSheight/2.0
1166 + ilayer * (fgkCH + fgkVspace);
1168 ypos = fgkClength[ilayer][2]/2.0 + fgkClength[ilayer][1];
1169 gMC->Gspos(cTagV, 1,"UTI1", xpos,ypos,zpos,0,"ONLY");
1170 gMC->Gspos(cTagV, 3,"UTI2", xpos,ypos,zpos,0,"ONLY");
1171 gMC->Gspos(cTagV, 5,"UTI3", xpos,ypos,zpos,0,"ONLY");
1173 ypos = - fgkClength[ilayer][2]/2.0 - fgkClength[ilayer][1];
1174 gMC->Gspos(cTagV, 2,"UTI1", xpos,ypos,zpos,0,"ONLY");
1175 gMC->Gspos(cTagV, 4,"UTI2", xpos,ypos,zpos,0,"ONLY");
1176 gMC->Gspos(cTagV, 6,"UTI3", xpos,ypos,zpos,0,"ONLY");
1181 // The horizontal connections between the cross bars
1184 const Int_t kNparSCH = 3;
1185 Float_t parSCH[kNparSCH];
1187 for (ilayer = 1; ilayer < kNlayer-1; ilayer++) {
1189 parSCH[0] = fgkCwidth[ilayer]/2.0;
1190 parSCH[1] = (fgkClength[ilayer+1][2]/2.0 + fgkClength[ilayer+1][1]
1191 - fgkClength[ilayer ][2]/2.0 - fgkClength[ilayer ][1])/2.0;
1192 parSCH[2] = kSCHhgt/2.0;
1194 snprintf(cTagV,kTag,"USH%01d",ilayer);
1195 gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCH,kNparSCH);
1197 ypos = fgkClength[ilayer][2]/2.0 + fgkClength[ilayer][1] + parSCH[1];
1198 zpos = fgkVrocsm + fgkSMpltT - kSCHhgt/2.0 - fgkSheight/2.0
1199 + (ilayer+1) * (fgkCH + fgkVspace);
1200 gMC->Gspos(cTagV,1,"UTI1", xpos,ypos,zpos,0,"ONLY");
1201 gMC->Gspos(cTagV,3,"UTI2", xpos,ypos,zpos,0,"ONLY");
1202 gMC->Gspos(cTagV,5,"UTI3", xpos,ypos,zpos,0,"ONLY");
1204 gMC->Gspos(cTagV,2,"UTI1", xpos,ypos,zpos,0,"ONLY");
1205 gMC->Gspos(cTagV,4,"UTI2", xpos,ypos,zpos,0,"ONLY");
1206 gMC->Gspos(cTagV,6,"UTI3", xpos,ypos,zpos,0,"ONLY");
1211 // The aymmetric flat frame in the middle
1214 // The envelope volume (aluminum)
1215 parTRD[0] = 87.60/2.0;
1216 parTRD[1] = 114.00/2.0;
1217 parTRD[2] = 1.20/2.0;
1218 parTRD[3] = 71.30/2.0;
1219 gMC->Gsvolu("USDB","TRD1",idtmed[1301-1],parTRD,kNparTRD);
1220 // Empty spaces (air)
1221 parTRP[ 0] = 1.20/2.0;
1224 parTRP[ 3] = 27.00/2.0;
1225 parTRP[ 4] = 50.60/2.0;
1226 parTRP[ 5] = 5.00/2.0;
1228 parTRP[ 7] = 27.00/2.0;
1229 parTRP[ 8] = 50.60/2.0;
1230 parTRP[ 9] = 5.00/2.0;
1232 gMC->Gsvolu("USD1","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1235 zpos = 27.00/2.0 - 71.3/2.0;
1236 gMC->Gspos("USD1",1,"USDB", xpos, ypos, zpos,matrix[2],"ONLY");
1237 // Empty spaces (air)
1238 parTRP[ 0] = 1.20/2.0;
1241 parTRP[ 3] = 33.00/2.0;
1242 parTRP[ 4] = 5.00/2.0;
1243 parTRP[ 5] = 62.10/2.0;
1245 parTRP[ 7] = 33.00/2.0;
1246 parTRP[ 8] = 5.00/2.0;
1247 parTRP[ 9] = 62.10/2.0;
1249 gMC->Gsvolu("USD2","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1252 zpos = 71.3/2.0 - 33.0/2.0;
1253 gMC->Gspos("USD2",1,"USDB", xpos, ypos, zpos,matrix[2],"ONLY");
1254 // Empty spaces (air)
1255 parBOX[ 0] = 22.50/2.0;
1256 parBOX[ 1] = 1.20/2.0;
1257 parBOX[ 2] = 70.50/2.0;
1258 gMC->Gsvolu("USD3","BOX ",idtmed[1302-1],parBOX,kNparBOX);
1262 gMC->Gspos("USD3",1,"USDB", xpos, ypos, zpos, 0,"ONLY");
1263 // Empty spaces (air)
1264 parTRP[ 0] = 1.20/2.0;
1267 parTRP[ 3] = 25.50/2.0;
1268 parTRP[ 4] = 5.00/2.0;
1269 parTRP[ 5] = 65.00/2.0;
1271 parTRP[ 7] = 25.50/2.0;
1272 parTRP[ 8] = 5.00/2.0;
1273 parTRP[ 9] = 65.00/2.0;
1275 gMC->Gsvolu("USD4","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1279 gMC->Gspos("USD4",1,"USDB", xpos, ypos, zpos,matrix[6],"ONLY");
1280 // Empty spaces (air)
1281 parTRP[ 0] = 1.20/2.0;
1284 parTRP[ 3] = 23.50/2.0;
1285 parTRP[ 4] = 63.50/2.0;
1286 parTRP[ 5] = 5.00/2.0;
1288 parTRP[ 7] = 23.50/2.0;
1289 parTRP[ 8] = 63.50/2.0;
1290 parTRP[ 9] = 5.00/2.0;
1292 gMC->Gsvolu("USD5","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1296 gMC->Gspos("USD5",1,"USDB", xpos, ypos, zpos,matrix[5],"ONLY");
1297 // Empty spaces (air)
1298 parTRP[ 0] = 1.20/2.0;
1301 parTRP[ 3] = 70.50/2.0;
1302 parTRP[ 4] = 4.50/2.0;
1303 parTRP[ 5] = 16.50/2.0;
1305 parTRP[ 7] = 70.50/2.0;
1306 parTRP[ 8] = 4.50/2.0;
1307 parTRP[ 9] = 16.50/2.0;
1309 gMC->Gsvolu("USD6","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1313 gMC->Gspos("USD6",1,"USDB", xpos, ypos, zpos,matrix[2],"ONLY");
1315 ypos = fgkClength[5][2]/2.0;
1317 gMC->Gspos("USDB",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1318 gMC->Gspos("USDB",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1319 gMC->Gspos("USDB",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1320 gMC->Gspos("USDB",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1321 gMC->Gspos("USDB",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1322 gMC->Gspos("USDB",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1323 // Upper bar (aluminum)
1324 parBOX[0] = 95.00/2.0;
1325 parBOX[1] = 1.20/2.0;
1326 parBOX[2] = 3.00/2.0;
1327 gMC->Gsvolu("USD7","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1329 ypos = fgkClength[5][2]/2.0;
1330 zpos = fgkSheight/2.0 - fgkSMpltT - 3.00/2.0;
1331 gMC->Gspos("USD7",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1332 gMC->Gspos("USD7",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1333 gMC->Gspos("USD7",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1334 gMC->Gspos("USD7",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1335 gMC->Gspos("USD7",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1336 gMC->Gspos("USD7",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1337 // Lower bar (aluminum)
1338 parBOX[0] = 90.22/2.0;
1339 parBOX[1] = 1.20/2.0;
1340 parBOX[2] = 1.74/2.0;
1341 gMC->Gsvolu("USD8","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1343 ypos = fgkClength[5][2]/2.0 - 0.1;
1344 zpos = -fgkSheight/2.0 + fgkSMpltT + 2.27;
1345 gMC->Gspos("USD8",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1346 gMC->Gspos("USD8",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1347 gMC->Gspos("USD8",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1348 gMC->Gspos("USD8",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1349 gMC->Gspos("USD8",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1350 gMC->Gspos("USD8",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1351 // Lower bar (aluminum)
1352 parBOX[0] = 82.60/2.0;
1353 parBOX[1] = 1.20/2.0;
1354 parBOX[2] = 1.40/2.0;
1355 gMC->Gsvolu("USD9","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1357 ypos = fgkClength[5][2]/2.0;
1358 zpos = -fgkSheight/2.0 + fgkSMpltT + 1.40/2.0;
1359 gMC->Gspos("USD9",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1360 gMC->Gspos("USD9",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1361 gMC->Gspos("USD9",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1362 gMC->Gspos("USD9",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1363 gMC->Gspos("USD9",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1364 gMC->Gspos("USD9",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1365 // Front sheet (aluminum)
1366 parTRP[ 0] = 0.10/2.0;
1369 parTRP[ 3] = 74.50/2.0;
1370 parTRP[ 4] = 31.70/2.0;
1371 parTRP[ 5] = 44.00/2.0;
1373 parTRP[ 7] = 74.50/2.0;
1374 parTRP[ 8] = 31.70/2.0;
1375 parTRP[ 9] = 44.00/2.0;
1377 gMC->Gsvolu("USDF","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1379 ypos = fgkClength[5][2]/2.0 + 1.20/2.0 + 0.10/2.0;
1381 gMC->Gspos("USDF",1,"UTI1", xpos, ypos, zpos,matrix[2],"ONLY");
1382 gMC->Gspos("USDF",2,"UTI1", xpos,-ypos, zpos,matrix[2],"ONLY");
1383 gMC->Gspos("USDF",3,"UTI2", xpos, ypos, zpos,matrix[2],"ONLY");
1384 gMC->Gspos("USDF",4,"UTI2", xpos,-ypos, zpos,matrix[2],"ONLY");
1385 gMC->Gspos("USDF",5,"UTI3", xpos, ypos, zpos,matrix[2],"ONLY");
1386 gMC->Gspos("USDF",6,"UTI3", xpos,-ypos, zpos,matrix[2],"ONLY");
1389 // The flat frame in front of the chambers
1392 // The envelope volume (aluminum)
1393 parTRD[0] = 90.00/2.0 - 0.1;
1394 parTRD[1] = 114.00/2.0 - 0.1;
1395 parTRD[2] = 1.50/2.0;
1396 parTRD[3] = 70.30/2.0;
1397 gMC->Gsvolu("USCB","TRD1",idtmed[1301-1],parTRD,kNparTRD);
1398 // Empty spaces (air)
1399 parTRD[0] = 87.00/2.0;
1400 parTRD[1] = 10.00/2.0;
1401 parTRD[2] = 1.50/2.0;
1402 parTRD[3] = 26.35/2.0;
1403 gMC->Gsvolu("USC1","TRD1",idtmed[1302-1],parTRD,kNparTRD);
1406 zpos = 26.35/2.0 - 70.3/2.0;
1407 gMC->Gspos("USC1",1,"USCB",xpos,ypos,zpos,0,"ONLY");
1408 // Empty spaces (air)
1409 parTRD[0] = 10.00/2.0;
1410 parTRD[1] = 111.00/2.0;
1411 parTRD[2] = 1.50/2.0;
1412 parTRD[3] = 35.05/2.0;
1413 gMC->Gsvolu("USC2","TRD1",idtmed[1302-1],parTRD,kNparTRD);
1416 zpos = 70.3/2.0 - 35.05/2.0;
1417 gMC->Gspos("USC2",1,"USCB",xpos,ypos,zpos,0,"ONLY");
1418 // Empty spaces (air)
1419 parTRP[ 0] = 1.50/2.0;
1422 parTRP[ 3] = 37.60/2.0;
1423 parTRP[ 4] = 63.90/2.0;
1424 parTRP[ 5] = 8.86/2.0;
1426 parTRP[ 7] = 37.60/2.0;
1427 parTRP[ 8] = 63.90/2.0;
1428 parTRP[ 9] = 8.86/2.0;
1430 gMC->Gsvolu("USC3","TRAP",idtmed[1302-1],parTRP,kNparTRP);
1434 gMC->Gspos("USC3",1,"USCB", xpos, ypos, zpos,matrix[4],"ONLY");
1435 gMC->Gspos("USC3",2,"USCB",-xpos, ypos, zpos,matrix[5],"ONLY");
1437 ypos = fgkClength[5][2]/2.0 + fgkClength[5][1] + fgkClength[5][0];
1439 gMC->Gspos("USCB",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1440 gMC->Gspos("USCB",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1441 gMC->Gspos("USCB",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1442 gMC->Gspos("USCB",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1443 gMC->Gspos("USCB",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1444 gMC->Gspos("USCB",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1445 // Upper bar (aluminum)
1446 parBOX[0] = 95.00/2.0;
1447 parBOX[1] = 1.50/2.0;
1448 parBOX[2] = 3.00/2.0;
1449 gMC->Gsvolu("USC4","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1451 ypos = fgkClength[5][2]/2.0 + fgkClength[5][1] + fgkClength[5][0];
1452 zpos = fgkSheight/2.0 - fgkSMpltT - 3.00/2.0;
1453 gMC->Gspos("USC4",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1454 gMC->Gspos("USC4",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1455 gMC->Gspos("USC4",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1456 gMC->Gspos("USC4",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1457 gMC->Gspos("USC4",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1458 gMC->Gspos("USC4",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1459 // Lower bar (aluminum)
1460 parBOX[0] = 90.22/2.0;
1461 parBOX[1] = 1.50/2.0;
1462 parBOX[2] = 2.00/2.0;
1463 gMC->Gsvolu("USC5","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1465 ypos = fgkClength[5][2]/2.0 + fgkClength[5][1] + fgkClength[5][0];
1466 zpos = -fgkSheight/2.0 + fgkSMpltT + 2.60;
1467 gMC->Gspos("USC5",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1468 gMC->Gspos("USC5",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1469 gMC->Gspos("USC5",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1470 gMC->Gspos("USC5",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1471 gMC->Gspos("USC5",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1472 gMC->Gspos("USC5",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1473 // Lower bar (aluminum)
1474 parBOX[0] = 82.60/2.0;
1475 parBOX[1] = 1.50/2.0;
1476 parBOX[2] = 1.60/2.0;
1477 gMC->Gsvolu("USC6","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1479 ypos = fgkClength[5][2]/2.0 + fgkClength[5][1] + fgkClength[5][0];
1480 zpos = -fgkSheight/2.0 + fgkSMpltT + 1.60/2.0;
1481 gMC->Gspos("USC6",1,"UTI1", xpos, ypos, zpos, 0,"ONLY");
1482 gMC->Gspos("USC6",2,"UTI1", xpos,-ypos, zpos, 0,"ONLY");
1483 gMC->Gspos("USC6",3,"UTI2", xpos, ypos, zpos, 0,"ONLY");
1484 gMC->Gspos("USC6",4,"UTI2", xpos,-ypos, zpos, 0,"ONLY");
1485 gMC->Gspos("USC6",5,"UTI3", xpos, ypos, zpos, 0,"ONLY");
1486 gMC->Gspos("USC6",6,"UTI3", xpos,-ypos, zpos, 0,"ONLY");
1489 // The long corner ledges
1492 const Int_t kNparSCL = 3;
1493 Float_t parSCL[kNparSCL];
1494 const Int_t kNparSCLb = 11;
1495 Float_t parSCLb[kNparSCLb];
1498 // Thickness of the corner ledges
1499 const Float_t kSCLthkUa = 0.6;
1500 const Float_t kSCLthkUb = 0.6;
1501 // Width of the corner ledges
1502 const Float_t kSCLwidUa = 3.2;
1503 const Float_t kSCLwidUb = 4.8;
1504 // Position of the corner ledges
1505 const Float_t kSCLposxUa = 0.7;
1506 const Float_t kSCLposxUb = 3.3;
1507 const Float_t kSCLposzUa = 1.65;
1508 const Float_t kSCLposzUb = 0.3;
1510 parSCL[0] = kSCLthkUa /2.0;
1511 parSCL[1] = fgkSlength/2.0;
1512 parSCL[2] = kSCLwidUa /2.0;
1513 gMC->Gsvolu("USL1","BOX ",idtmed[1301-1],parSCL,kNparSCL);
1514 xpos = fgkSwidth2/2.0 - fgkSMpltT - kSCLposxUa;
1516 zpos = fgkSheight/2.0 - fgkSMpltT - kSCLposzUa;
1517 gMC->Gspos("USL1",1,"UTI1", xpos,ypos,zpos,matrix[0],"ONLY");
1519 gMC->Gspos("USL1",2,"UTI1", xpos,ypos,zpos,matrix[1],"ONLY");
1521 parSCL[0] = kSCLwidUb /2.0;
1522 parSCL[1] = fgkSlength/2.0;
1523 parSCL[2] = kSCLthkUb /2.0;
1524 gMC->Gsvolu("USL2","BOX ",idtmed[1301-1],parSCL,kNparSCL);
1525 xpos = fgkSwidth2/2.0 - fgkSMpltT - kSCLposxUb;
1527 zpos = fgkSheight/2.0 - fgkSMpltT - kSCLposzUb;
1528 gMC->Gspos("USL2",1,"UTI1", xpos,ypos,zpos, 0,"ONLY");
1529 gMC->Gspos("USL2",3,"UTI2", xpos,ypos,zpos, 0,"ONLY");
1530 gMC->Gspos("USL2",5,"UTI3", xpos,ypos,zpos, 0,"ONLY");
1532 gMC->Gspos("USL2",2,"UTI1", xpos,ypos,zpos, 0,"ONLY");
1533 gMC->Gspos("USL2",4,"UTI2", xpos,ypos,zpos, 0,"ONLY");
1534 gMC->Gspos("USL2",6,"UTI3", xpos,ypos,zpos, 0,"ONLY");
1537 // Thickness of the corner ledges
1538 const Float_t kSCLthkLa = 2.464;
1539 const Float_t kSCLthkLb = 1.0;
1540 // Width of the corner ledges
1541 const Float_t kSCLwidLa = 8.3;
1542 const Float_t kSCLwidLb = 4.0;
1543 // Position of the corner ledges
1544 const Float_t kSCLposxLa = (3.0 * kSCLthkLb - kSCLthkLa) / 4.0 + 0.05;
1545 const Float_t kSCLposxLb = kSCLthkLb + kSCLwidLb/2.0 + 0.05;
1546 const Float_t kSCLposzLa = kSCLwidLa/2.0;
1547 const Float_t kSCLposzLb = kSCLthkLb/2.0;
1549 // Trapezoidal shape
1550 parSCLb[ 0] = fgkSlength/2.0;
1553 parSCLb[ 3] = kSCLwidLa /2.0;
1554 parSCLb[ 4] = kSCLthkLb /2.0;
1555 parSCLb[ 5] = kSCLthkLa /2.0;
1557 parSCLb[ 7] = kSCLwidLa /2.0;
1558 parSCLb[ 8] = kSCLthkLb /2.0;
1559 parSCLb[ 9] = kSCLthkLa /2.0;
1561 gMC->Gsvolu("USL3","TRAP",idtmed[1301-1],parSCLb,kNparSCLb);
1562 xpos = fgkSwidth1/2.0 - fgkSMpltT - kSCLposxLa;
1564 zpos = - fgkSheight/2.0 + fgkSMpltT + kSCLposzLa;
1565 gMC->Gspos("USL3",1,"UTI1", xpos,ypos,zpos,matrix[2],"ONLY");
1566 gMC->Gspos("USL3",3,"UTI2", xpos,ypos,zpos,matrix[2],"ONLY");
1567 gMC->Gspos("USL3",5,"UTI3", xpos,ypos,zpos,matrix[2],"ONLY");
1569 gMC->Gspos("USL3",2,"UTI1", xpos,ypos,zpos,matrix[3],"ONLY");
1570 gMC->Gspos("USL3",4,"UTI2", xpos,ypos,zpos,matrix[3],"ONLY");
1571 gMC->Gspos("USL3",6,"UTI3", xpos,ypos,zpos,matrix[3],"ONLY");
1573 parSCL[0] = kSCLwidLb /2.0;
1574 parSCL[1] = fgkSlength/2.0;
1575 parSCL[2] = kSCLthkLb /2.0;
1576 gMC->Gsvolu("USL4","BOX ",idtmed[1301-1],parSCL,kNparSCL);
1577 xpos = fgkSwidth1/2.0 - fgkSMpltT - kSCLposxLb;
1579 zpos = - fgkSheight/2.0 + fgkSMpltT + kSCLposzLb;
1580 gMC->Gspos("USL4",1,"UTI1", xpos,ypos,zpos, 0,"ONLY");
1581 gMC->Gspos("USL4",3,"UTI2", xpos,ypos,zpos, 0,"ONLY");
1582 gMC->Gspos("USL4",5,"UTI3", xpos,ypos,zpos, 0,"ONLY");
1584 gMC->Gspos("USL4",2,"UTI1", xpos,ypos,zpos, 0,"ONLY");
1585 gMC->Gspos("USL4",4,"UTI2", xpos,ypos,zpos, 0,"ONLY");
1586 gMC->Gspos("USL4",6,"UTI3", xpos,ypos,zpos, 0,"ONLY");
1589 // Aluminum plates in the front part of the super modules
1592 const Int_t kNparTrd = 4;
1593 Float_t parTrd[kNparTrd];
1594 parTrd[0] = fgkSwidth1/2.0 - 2.5;
1595 parTrd[1] = fgkSwidth2/2.0 - 2.5;
1596 parTrd[2] = fgkSMpltT /2.0;
1597 parTrd[3] = fgkSheight/2.0 - 1.0;
1598 gMC->Gsvolu("UTA1","TRD1",idtmed[1301-1],parTrd,kNparTrd);
1600 ypos = fgkSMpltT/2.0 - fgkFlength/2.0;
1602 gMC->Gspos("UTA1",1,"UTF1",xpos, ypos,zpos, 0,"ONLY");
1603 gMC->Gspos("UTA1",2,"UTF2",xpos,-ypos,zpos, 0,"ONLY");
1605 const Int_t kNparPlt = 3;
1606 Float_t parPlt[kNparPlt];
1610 gMC->Gsvolu("UTA2","BOX ",idtmed[1301-1],parPlt,0);
1613 zpos = fgkSheight/2.0 - fgkSMpltT/2.0;
1614 parPlt[0] = fgkSwidth2/2.0 - 0.2;
1615 parPlt[1] = fgkFlength/2.0;
1616 parPlt[2] = fgkSMpltT /2.0;
1617 gMC->Gsposp("UTA2",1,"UTF2",xpos,ypos,zpos
1618 , 0,"ONLY",parPlt,kNparPlt);
1619 xpos = (fgkSwidth1 + fgkSwidth2)/4.0 - fgkSMpltT/2.0 - 0.0016;
1622 parPlt[0] = fgkSMpltT /2.0;
1623 parPlt[1] = fgkFlength/2.0;
1624 parPlt[2] = fgkSheight/2.0;
1625 gMC->Gsposp("UTA2",2,"UTF2", xpos,ypos,zpos
1626 ,matrix[0],"ONLY",parPlt,kNparPlt);
1627 gMC->Gsposp("UTA2",3,"UTF2",-xpos,ypos,zpos
1628 ,matrix[1],"ONLY",parPlt,kNparPlt);
1630 // Additional aluminum bar
1631 parBOX[0] = 80.0/2.0;
1632 parBOX[1] = 1.0/2.0;
1633 parBOX[2] = 10.0/2.0;
1634 gMC->Gsvolu("UTA3","BOX ",idtmed[1301-1],parBOX,kNparBOX);
1636 ypos = 1.0/2.0 + fgkSMpltT - fgkFlength/2.0;
1637 zpos = fgkSheight/2.0 - 1.5 - 10.0/2.0;
1638 gMC->Gspos("UTA3",1,"UTF1", xpos, ypos, zpos, 0,"ONLY");
1639 gMC->Gspos("UTA3",2,"UTF2", xpos,-ypos, zpos, 0,"ONLY");
1643 //_____________________________________________________________________________
1644 void AliTRDgeometry::CreateServices(Int_t *idtmed)
1647 // Create the geometry of the services
1649 // Names of the TRD services volumina
1651 // UTC1 Cooling arterias (Al)
1652 // UTC2 Cooling arterias (Water)
1653 // UUxx Volumes for the services at the chambers (Air)
1654 // UMCM Readout MCMs (G10/Cu/Si)
1655 // UDCS DCSs boards (G10/Cu)
1656 // UTP1 Power bars (Cu)
1657 // UTCP Cooling pipes (Fe)
1658 // UTCH Cooling pipes (Water)
1659 // UTPL Power lines (Cu)
1660 // UTGD Gas distribution box (V2A)
1670 const Int_t kTag = 100;
1673 const Int_t kNparBox = 3;
1674 Float_t parBox[kNparBox];
1676 const Int_t kNparTube = 3;
1677 Float_t parTube[kNparTube];
1679 // Services inside the baby frame
1680 const Float_t kBBMdz = 223.0;
1681 const Float_t kBBSdz = 8.5;
1683 // Services inside the back frame
1684 const Float_t kBFMdz = 118.0;
1685 const Float_t kBFSdz = 8.5;
1687 // The rotation matrices
1688 const Int_t kNmatrix = 10;
1689 Int_t matrix[kNmatrix];
1690 gMC->Matrix(matrix[0], 100.0, 0.0, 90.0, 90.0, 10.0, 0.0); // rotation around y-axis
1691 gMC->Matrix(matrix[1], 80.0, 0.0, 90.0, 90.0, 10.0, 180.0); // rotation around y-axis
1692 gMC->Matrix(matrix[2], 0.0, 0.0, 90.0, 90.0, 90.0, 0.0);
1693 gMC->Matrix(matrix[3], 180.0, 0.0, 90.0, 90.0, 90.0, 180.0);
1694 gMC->Matrix(matrix[4], 90.0, 0.0, 0.0, 0.0, 90.0, 90.0);
1695 gMC->Matrix(matrix[5], 100.0, 0.0, 90.0, 270.0, 10.0, 0.0);
1696 gMC->Matrix(matrix[6], 80.0, 0.0, 90.0, 270.0, 10.0, 180.0);
1697 gMC->Matrix(matrix[7], 90.0, 10.0, 90.0, 100.0, 0.0, 0.0); // rotation around z-axis
1698 gMC->Matrix(matrix[8], 90.0, 350.0, 90.0, 80.0, 0.0, 0.0); // rotation around z-axis
1699 gMC->Matrix(matrix[9], 90.0, 90.0, 90.0, 180.0, 0.0, 0.0); // rotation around z-axis
1702 // The cooling arterias
1705 // Width of the cooling arterias
1706 const Float_t kCOLwid = 0.8;
1707 // Height of the cooling arterias
1708 const Float_t kCOLhgt = 6.5;
1709 // Positioning of the cooling
1710 const Float_t kCOLposx = 1.0;
1711 const Float_t kCOLposz = -1.2;
1712 // Thickness of the walls of the cooling arterias
1713 const Float_t kCOLthk = 0.1;
1714 const Int_t kNparCOL = 3;
1715 Float_t parCOL[kNparCOL];
1719 gMC->Gsvolu("UTC1","BOX ",idtmed[1308-1],parCOL,0);
1720 gMC->Gsvolu("UTC3","BOX ",idtmed[1308-1],parCOL,0);
1721 parCOL[0] = kCOLwid/2.0 - kCOLthk;
1723 parCOL[2] = kCOLhgt/2.0 - kCOLthk;
1724 gMC->Gsvolu("UTC2","BOX ",idtmed[1314-1],parCOL,kNparCOL);
1725 gMC->Gsvolu("UTC4","BOX ",idtmed[1314-1],parCOL,kNparCOL);
1730 gMC->Gspos("UTC2",1,"UTC1", xpos,ypos,zpos,0,"ONLY");
1731 gMC->Gspos("UTC4",1,"UTC3", xpos,ypos,zpos,0,"ONLY");
1733 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1735 // Along the chambers
1736 xpos = fgkCwidth[ilayer]/2.0 + kCOLwid/2.0 + kCOLposx;
1738 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1739 + kCOLhgt/2.0 - fgkSheight/2.0 + kCOLposz
1740 + ilayer * (fgkCH + fgkVspace);
1741 parCOL[0] = kCOLwid /2.0;
1742 parCOL[1] = fgkSlength/2.0;
1743 parCOL[2] = kCOLhgt /2.0;
1744 gMC->Gsposp("UTC1",ilayer ,"UTI1", xpos,ypos,zpos
1745 ,matrix[0],"ONLY",parCOL,kNparCOL);
1746 gMC->Gsposp("UTC1",ilayer+ kNlayer,"UTI1",-xpos,ypos,zpos
1747 ,matrix[1],"ONLY",parCOL,kNparCOL);
1748 gMC->Gsposp("UTC1",ilayer+6*kNlayer,"UTI2", xpos,ypos,zpos
1749 ,matrix[0],"ONLY",parCOL,kNparCOL);
1750 gMC->Gsposp("UTC1",ilayer+7*kNlayer,"UTI2",-xpos,ypos,zpos
1751 ,matrix[1],"ONLY",parCOL,kNparCOL);
1752 gMC->Gsposp("UTC1",ilayer+8*kNlayer ,"UTI3", xpos,ypos,zpos
1753 ,matrix[0],"ONLY",parCOL,kNparCOL);
1754 gMC->Gsposp("UTC1",ilayer+9*kNlayer,"UTI3",-xpos,ypos,zpos
1755 ,matrix[1],"ONLY",parCOL,kNparCOL);
1757 // Front of supermodules
1758 xpos = fgkCwidth[ilayer]/2.0 + kCOLwid/2.0 + kCOLposx;
1760 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1761 + kCOLhgt/2.0 - fgkSheight/2.0 + kCOLposz
1762 + ilayer * (fgkCH + fgkVspace);
1763 parCOL[0] = kCOLwid /2.0;
1764 parCOL[1] = fgkFlength/2.0;
1765 parCOL[2] = kCOLhgt /2.0;
1766 gMC->Gsposp("UTC3",ilayer+2*kNlayer,"UTF1", xpos,ypos,zpos
1767 ,matrix[0],"ONLY",parCOL,kNparCOL);
1768 gMC->Gsposp("UTC3",ilayer+3*kNlayer,"UTF1",-xpos,ypos,zpos
1769 ,matrix[1],"ONLY",parCOL,kNparCOL);
1770 gMC->Gsposp("UTC3",ilayer+4*kNlayer,"UTF2", xpos,ypos,zpos
1771 ,matrix[0],"ONLY",parCOL,kNparCOL);
1772 gMC->Gsposp("UTC3",ilayer+5*kNlayer,"UTF2",-xpos,ypos,zpos
1773 ,matrix[1],"ONLY",parCOL,kNparCOL);
1777 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1780 xpos = fgkCwidth[ilayer]/2.0 + kCOLwid/2.0 + kCOLposx - 2.5;
1781 ypos = kBBSdz/2.0 - kBBMdz/2.0;
1782 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1783 + kCOLhgt/2.0 - fgkSheight/2.0 + kCOLposz
1784 + ilayer * (fgkCH + fgkVspace);
1785 parCOL[0] = kCOLwid/2.0;
1786 parCOL[1] = kBBSdz /2.0;
1787 parCOL[2] = kCOLhgt/2.0;
1788 gMC->Gsposp("UTC3",ilayer+6*kNlayer,"BBTRD", xpos, ypos, zpos
1789 ,matrix[0],"ONLY",parCOL,kNparCOL);
1790 gMC->Gsposp("UTC3",ilayer+7*kNlayer,"BBTRD",-xpos, ypos, zpos
1791 ,matrix[1],"ONLY",parCOL,kNparCOL);
1795 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1798 xpos = fgkCwidth[ilayer]/2.0 + kCOLwid/2.0 + kCOLposx - 0.3;
1799 ypos = -kBFSdz/2.0 + kBFMdz/2.0;
1800 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1801 + kCOLhgt/2.0 - fgkSheight/2.0 + kCOLposz
1802 + ilayer * (fgkCH + fgkVspace);
1803 parCOL[0] = kCOLwid/2.0;
1804 parCOL[1] = kBFSdz /2.0;
1805 parCOL[2] = kCOLhgt/2.0;
1806 gMC->Gsposp("UTC3",ilayer+6*kNlayer,"BFTRD", xpos,ypos,zpos
1807 ,matrix[0],"ONLY",parCOL,kNparCOL);
1808 gMC->Gsposp("UTC3",ilayer+7*kNlayer,"BFTRD",-xpos,ypos,zpos
1809 ,matrix[1],"ONLY",parCOL,kNparCOL);
1813 // The upper most layer
1814 // Along the chambers
1815 xpos = fgkCwidth[5]/2.0 - kCOLhgt/2.0 - 1.3;
1817 zpos = fgkSheight/2.0 - fgkSMpltT - 0.4 - kCOLwid/2.0;
1818 parCOL[0] = kCOLwid /2.0;
1819 parCOL[1] = fgkSlength/2.0;
1820 parCOL[2] = kCOLhgt /2.0;
1821 gMC->Gsposp("UTC1",6 ,"UTI1", xpos,ypos,zpos
1822 ,matrix[3],"ONLY",parCOL,kNparCOL);
1823 gMC->Gsposp("UTC1",6+ kNlayer,"UTI1",-xpos,ypos,zpos
1824 ,matrix[3],"ONLY",parCOL,kNparCOL);
1825 gMC->Gsposp("UTC1",6+6*kNlayer,"UTI2", xpos,ypos,zpos
1826 ,matrix[3],"ONLY",parCOL,kNparCOL);
1827 gMC->Gsposp("UTC1",6+7*kNlayer,"UTI2",-xpos,ypos,zpos
1828 ,matrix[3],"ONLY",parCOL,kNparCOL);
1829 gMC->Gsposp("UTC1",6+8*kNlayer,"UTI3", xpos,ypos,zpos
1830 ,matrix[3],"ONLY",parCOL,kNparCOL);
1831 gMC->Gsposp("UTC1",6+9*kNlayer,"UTI3",-xpos,ypos,zpos
1832 ,matrix[3],"ONLY",parCOL,kNparCOL);
1833 // Front of supermodules
1834 xpos = fgkCwidth[5]/2.0 - kCOLhgt/2.0 - 1.3;
1836 zpos = fgkSheight/2.0 - fgkSMpltT - 0.4 - kCOLwid/2.0;
1837 parCOL[0] = kCOLwid /2.0;
1838 parCOL[1] = fgkFlength/2.0;
1839 parCOL[2] = kCOLhgt /2.0;
1840 gMC->Gsposp("UTC3",6+2*kNlayer,"UTF1", xpos,ypos,zpos
1841 ,matrix[3],"ONLY",parCOL,kNparCOL);
1842 gMC->Gsposp("UTC3",6+3*kNlayer,"UTF1",-xpos,ypos,zpos
1843 ,matrix[3],"ONLY",parCOL,kNparCOL);
1844 gMC->Gsposp("UTC3",6+4*kNlayer,"UTF2", xpos,ypos,zpos
1845 ,matrix[3],"ONLY",parCOL,kNparCOL);
1846 gMC->Gsposp("UTC3",6+5*kNlayer,"UTF2",-xpos,ypos,zpos
1847 ,matrix[3],"ONLY",parCOL,kNparCOL);
1849 xpos = fgkCwidth[5]/2.0 - kCOLhgt/2.0 - 3.1;
1850 ypos = kBBSdz/2.0 - kBBMdz/2.0;
1851 zpos = fgkSheight/2.0 - fgkSMpltT - 0.4 - kCOLwid/2.0;
1852 parCOL[0] = kCOLwid/2.0;
1853 parCOL[1] = kBBSdz /2.0;
1854 parCOL[2] = kCOLhgt/2.0;
1855 gMC->Gsposp("UTC3",6+6*kNlayer,"BBTRD", xpos, ypos, zpos
1856 ,matrix[3],"ONLY",parCOL,kNparCOL);
1857 gMC->Gsposp("UTC3",6+7*kNlayer,"BBTRD",-xpos, ypos, zpos
1858 ,matrix[3],"ONLY",parCOL,kNparCOL);
1860 xpos = fgkCwidth[5]/2.0 - kCOLhgt/2.0 - 1.3;
1861 ypos = -kBFSdz/2.0 + kBFMdz/2.0;
1862 zpos = fgkSheight/2.0 - fgkSMpltT - 0.4 - kCOLwid/2.0;
1863 parCOL[0] = kCOLwid/2.0;
1864 parCOL[1] = kBFSdz /2.0;
1865 parCOL[2] = kCOLhgt/2.0;
1866 gMC->Gsposp("UTC3",6+6*kNlayer,"BFTRD", xpos,ypos,zpos
1867 ,matrix[3],"ONLY",parCOL,kNparCOL);
1868 gMC->Gsposp("UTC3",6+7*kNlayer,"BFTRD",-xpos,ypos,zpos
1869 ,matrix[3],"ONLY",parCOL,kNparCOL);
1872 // The power bus bars
1875 const Float_t kPWRwid = 0.6;
1876 // Increase the height of the power bus bars to take into
1877 // account the material of additional cables, etc.
1878 const Float_t kPWRhgtA = 5.0 + 0.2;
1879 const Float_t kPWRhgtB = 5.0;
1880 const Float_t kPWRposx = 2.0;
1881 const Float_t kPWRposz = 0.1;
1882 const Int_t kNparPWR = 3;
1883 Float_t parPWR[kNparPWR];
1887 gMC->Gsvolu("UTP1","BOX ",idtmed[1325-1],parPWR,0);
1888 gMC->Gsvolu("UTP3","BOX ",idtmed[1325-1],parPWR,0);
1890 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1892 // Along the chambers
1893 xpos = fgkCwidth[ilayer]/2.0 + kPWRwid/2.0 + kPWRposx;
1895 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1896 + kPWRhgtA/2.0 - fgkSheight/2.0 + kPWRposz
1897 + ilayer * (fgkCH + fgkVspace);
1898 parPWR[0] = kPWRwid /2.0;
1899 parPWR[1] = fgkSlength/2.0;
1900 parPWR[2] = kPWRhgtA /2.0;
1901 gMC->Gsposp("UTP1",ilayer ,"UTI1", xpos,ypos,zpos
1902 ,matrix[0],"ONLY",parPWR,kNparPWR);
1903 gMC->Gsposp("UTP1",ilayer+ kNlayer,"UTI1",-xpos,ypos,zpos
1904 ,matrix[1],"ONLY",parPWR,kNparPWR);
1905 gMC->Gsposp("UTP1",ilayer+6*kNlayer,"UTI2", xpos,ypos,zpos
1906 ,matrix[0],"ONLY",parPWR,kNparPWR);
1907 gMC->Gsposp("UTP1",ilayer+7*kNlayer,"UTI2",-xpos,ypos,zpos
1908 ,matrix[1],"ONLY",parPWR,kNparPWR);
1909 gMC->Gsposp("UTP1",ilayer+8*kNlayer,"UTI3", xpos,ypos,zpos
1910 ,matrix[0],"ONLY",parPWR,kNparPWR);
1911 gMC->Gsposp("UTP1",ilayer+9*kNlayer,"UTI3",-xpos,ypos,zpos
1912 ,matrix[1],"ONLY",parPWR,kNparPWR);
1914 // Front of supermodule
1915 xpos = fgkCwidth[ilayer]/2.0 + kPWRwid/2.0 + kPWRposx;
1917 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1918 + kPWRhgtA/2.0 - fgkSheight/2.0 + kPWRposz
1919 + ilayer * (fgkCH + fgkVspace);
1920 parPWR[0] = kPWRwid /2.0;
1921 parPWR[1] = fgkFlength/2.0;
1922 parPWR[2] = kPWRhgtA /2.0;
1923 gMC->Gsposp("UTP3",ilayer+2*kNlayer,"UTF1", xpos,ypos,zpos
1924 ,matrix[0],"ONLY",parPWR,kNparPWR);
1925 gMC->Gsposp("UTP3",ilayer+3*kNlayer,"UTF1",-xpos,ypos,zpos
1926 ,matrix[1],"ONLY",parPWR,kNparPWR);
1927 gMC->Gsposp("UTP3",ilayer+4*kNlayer,"UTF2", xpos,ypos,zpos
1928 ,matrix[0],"ONLY",parPWR,kNparPWR);
1929 gMC->Gsposp("UTP3",ilayer+5*kNlayer,"UTF2",-xpos,ypos,zpos
1930 ,matrix[1],"ONLY",parPWR,kNparPWR);
1934 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1937 xpos = fgkCwidth[ilayer]/2.0 + kPWRwid/2.0 + kPWRposx - 2.5;
1938 ypos = kBBSdz/2.0 - kBBMdz/2.0;
1939 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1940 + kPWRhgtB/2.0 - fgkSheight/2.0 + kPWRposz
1941 + ilayer * (fgkCH + fgkVspace);
1942 parPWR[0] = kPWRwid /2.0;
1943 parPWR[1] = kBBSdz /2.0;
1944 parPWR[2] = kPWRhgtB/2.0;
1945 gMC->Gsposp("UTP3",ilayer+6*kNlayer,"BBTRD", xpos, ypos, zpos
1946 ,matrix[0],"ONLY",parPWR,kNparPWR);
1947 gMC->Gsposp("UTP3",ilayer+7*kNlayer,"BBTRD",-xpos, ypos, zpos
1948 ,matrix[1],"ONLY",parPWR,kNparPWR);
1952 for (ilayer = 1; ilayer < kNlayer; ilayer++) {
1955 xpos = fgkCwidth[ilayer]/2.0 + kPWRwid/2.0 + kPWRposx - 0.3;
1956 ypos = -kBFSdz/2.0 + kBFMdz/2.0;
1957 zpos = fgkVrocsm + fgkSMpltT - fgkCalZpos
1958 + kPWRhgtB/2.0 - fgkSheight/2.0 + kPWRposz
1959 + ilayer * (fgkCH + fgkVspace);
1960 parPWR[0] = kPWRwid /2.0;
1961 parPWR[1] = kBFSdz /2.0;
1962 parPWR[2] = kPWRhgtB/2.0;
1963 gMC->Gsposp("UTP3",ilayer+8*kNlayer,"BFTRD", xpos,ypos,zpos
1964 ,matrix[0],"ONLY",parPWR,kNparPWR);
1965 gMC->Gsposp("UTP3",ilayer+9*kNlayer,"BFTRD",-xpos,ypos,zpos
1966 ,matrix[1],"ONLY",parPWR,kNparPWR);
1970 // The upper most layer
1971 // Along the chambers
1972 xpos = fgkCwidth[5]/2.0 + kPWRhgtB/2.0 - 1.3;
1974 zpos = fgkSheight/2.0 - fgkSMpltT - 0.6 - kPWRwid/2.0;
1975 parPWR[0] = kPWRwid /2.0;
1976 parPWR[1] = fgkSlength/2.0;
1977 parPWR[2] = kPWRhgtB /2.0 ;
1978 gMC->Gsposp("UTP1",6 ,"UTI1", xpos,ypos,zpos
1979 ,matrix[3],"ONLY",parPWR,kNparPWR);
1980 gMC->Gsposp("UTP1",6+ kNlayer,"UTI1",-xpos,ypos,zpos
1981 ,matrix[3],"ONLY",parPWR,kNparPWR);
1982 gMC->Gsposp("UTP1",6+6*kNlayer,"UTI2", xpos,ypos,zpos
1983 ,matrix[3],"ONLY",parPWR,kNparPWR);
1984 gMC->Gsposp("UTP1",6+7*kNlayer,"UTI2",-xpos,ypos,zpos
1985 ,matrix[3],"ONLY",parPWR,kNparPWR);
1986 gMC->Gsposp("UTP1",6+8*kNlayer,"UTI3", xpos,ypos,zpos
1987 ,matrix[3],"ONLY",parPWR,kNparPWR);
1988 gMC->Gsposp("UTP1",6+9*kNlayer,"UTI3",-xpos,ypos,zpos
1989 ,matrix[3],"ONLY",parPWR,kNparPWR);
1990 // Front of supermodules
1991 xpos = fgkCwidth[5]/2.0 + kPWRhgtB/2.0 - 1.3;
1993 zpos = fgkSheight/2.0 - fgkSMpltT - 0.6 - kPWRwid/2.0;
1994 parPWR[0] = kPWRwid /2.0;
1995 parPWR[1] = fgkFlength/2.0;
1996 parPWR[2] = kPWRhgtB /2.0;
1997 gMC->Gsposp("UTP3",6+2*kNlayer,"UTF1", xpos,ypos,zpos
1998 ,matrix[3],"ONLY",parPWR,kNparPWR);
1999 gMC->Gsposp("UTP3",6+3*kNlayer,"UTF1",-xpos,ypos,zpos
2000 ,matrix[3],"ONLY",parPWR,kNparPWR);
2001 gMC->Gsposp("UTP3",6+4*kNlayer,"UTF2", xpos,ypos,zpos
2002 ,matrix[3],"ONLY",parPWR,kNparPWR);
2003 gMC->Gsposp("UTP3",6+5*kNlayer,"UTF2",-xpos,ypos,zpos
2004 ,matrix[3],"ONLY",parPWR,kNparPWR);
2006 xpos = fgkCwidth[5]/2.0 + kPWRhgtB/2.0 - 3.0;
2007 ypos = kBBSdz/2.0 - kBBMdz/2.0;
2008 zpos = fgkSheight/2.0 - fgkSMpltT - 0.6 - kPWRwid/2.0;
2009 parPWR[0] = kPWRwid /2.0;
2010 parPWR[1] = kBBSdz /2.0;
2011 parPWR[2] = kPWRhgtB/2.0;
2012 gMC->Gsposp("UTP3",6+6*kNlayer,"BBTRD", xpos, ypos, zpos
2013 ,matrix[3],"ONLY",parPWR,kNparPWR);
2014 gMC->Gsposp("UTP3",6+7*kNlayer,"BBTRD",-xpos, ypos, zpos
2015 ,matrix[3],"ONLY",parPWR,kNparPWR);
2017 xpos = fgkCwidth[5]/2.0 + kPWRhgtB/2.0 - 1.3;
2018 ypos = -kBFSdz/2.0 + kBFMdz/2.0;
2019 zpos = fgkSheight/2.0 - fgkSMpltT - 0.6 - kPWRwid/2.0;
2020 parPWR[0] = kPWRwid /2.0;
2021 parPWR[1] = kBFSdz /2.0;
2022 parPWR[2] = kPWRhgtB/2.0;
2023 gMC->Gsposp("UTP3",6+8*kNlayer,"BFTRD", xpos,ypos,zpos
2024 ,matrix[3],"ONLY",parPWR,kNparPWR);
2025 gMC->Gsposp("UTP3",6+9*kNlayer,"BFTRD",-xpos,ypos,zpos
2026 ,matrix[3],"ONLY",parPWR,kNparPWR);
2029 // The gas tubes connecting the chambers in the super modules with holes
2030 // Material: Stainless steel
2034 parTube[1] = 2.2/2.0;
2035 parTube[2] = fgkClength[5][2]/2.0 - fgkHspace/2.0;
2036 gMC->Gsvolu("UTG1","TUBE",idtmed[1308-1],parTube,kNparTube);
2038 parTube[1] = 2.1/2.0;
2039 parTube[2] = fgkClength[5][2]/2.0 - fgkHspace/2.0;
2040 gMC->Gsvolu("UTG2","TUBE",idtmed[1309-1],parTube,kNparTube);
2044 gMC->Gspos("UTG2",1,"UTG1",xpos,ypos,zpos,0,"ONLY");
2045 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2046 xpos = fgkCwidth[ilayer]/2.0 + kCOLwid/2.0 - 1.5;
2048 zpos = fgkVrocsm + fgkSMpltT + kCOLhgt/2.0 - fgkSheight/2.0 + 5.0
2049 + ilayer * (fgkCH + fgkVspace);
2050 gMC->Gspos("UTG1",1+ilayer,"UTI3", xpos, ypos, zpos,matrix[4],"ONLY");
2051 gMC->Gspos("UTG1",7+ilayer,"UTI3",-xpos, ypos, zpos,matrix[4],"ONLY");
2055 // The volumes for the services at the chambers
2058 const Int_t kNparServ = 3;
2059 Float_t parServ[kNparServ];
2061 for (istack = 0; istack < kNstack; istack++) {
2062 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2064 Int_t iDet = GetDetectorSec(ilayer,istack);
2066 snprintf(cTagV,kTag,"UU%02d",iDet);
2067 parServ[0] = fgkCwidth[ilayer] /2.0;
2068 parServ[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
2069 parServ[2] = fgkCsvH /2.0;
2070 gMC->Gsvolu(cTagV,"BOX",idtmed[1302-1],parServ,kNparServ);
2076 // The cooling pipes inside the service volumes
2079 // The cooling pipes
2083 gMC->Gsvolu("UTCP","TUBE",idtmed[1324-1],parTube,0);
2084 // The cooling water
2086 parTube[1] = 0.2/2.0;
2088 gMC->Gsvolu("UTCH","TUBE",idtmed[1314-1],parTube,kNparTube);
2089 // Water inside the cooling pipe
2093 gMC->Gspos("UTCH",1,"UTCP",xpos,ypos,zpos,0,"ONLY");
2095 // Position the cooling pipes in the mother volume
2096 for (istack = 0; istack < kNstack; istack++) {
2097 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2098 Int_t iDet = GetDetectorSec(ilayer,istack);
2099 Int_t iCopy = GetDetector(ilayer,istack,0) * 100;
2100 Int_t nMCMrow = GetRowMax(ilayer,istack,0);
2101 Float_t ySize = (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2102 / ((Float_t) nMCMrow);
2103 snprintf(cTagV,kTag,"UU%02d",iDet);
2104 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
2106 ypos = (0.5 + iMCMrow) * ySize
2107 - fgkClength[ilayer][istack]/2.0 + fgkHspace/2.0;
2108 zpos = 0.0 + 0.742/2.0;
2109 // The cooling pipes
2111 parTube[1] = 0.3/2.0; // Thickness of the cooling pipes
2112 parTube[2] = fgkCwidth[ilayer]/2.0;
2113 gMC->Gsposp("UTCP",iCopy+iMCMrow,cTagV,xpos,ypos,zpos
2114 ,matrix[2],"ONLY",parTube,kNparTube);
2123 // The copper power lines
2127 gMC->Gsvolu("UTPL","TUBE",idtmed[1305-1],parTube,0);
2129 // Position the power lines in the mother volume
2130 for (istack = 0; istack < kNstack; istack++) {
2131 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2132 Int_t iDet = GetDetectorSec(ilayer,istack);
2133 Int_t iCopy = GetDetector(ilayer,istack,0) * 100;
2134 Int_t nMCMrow = GetRowMax(ilayer,istack,0);
2135 Float_t ySize = (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2136 / ((Float_t) nMCMrow);
2137 snprintf(cTagV,kTag,"UU%02d",iDet);
2138 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
2140 ypos = (0.5 + iMCMrow) * ySize - 1.0
2141 - fgkClength[ilayer][istack]/2.0 + fgkHspace/2.0;
2142 zpos = -0.4 + 0.742/2.0;
2144 parTube[1] = 0.2/2.0; // Thickness of the power lines
2145 parTube[2] = fgkCwidth[ilayer]/2.0;
2146 gMC->Gsposp("UTPL",iCopy+iMCMrow,cTagV,xpos,ypos,zpos
2147 ,matrix[2],"ONLY",parTube,kNparTube);
2156 const Float_t kMCMx = 3.0;
2157 const Float_t kMCMy = 3.0;
2158 const Float_t kMCMz = 0.3;
2160 const Float_t kMCMpcTh = 0.1;
2161 const Float_t kMCMcuTh = 0.0025;
2162 const Float_t kMCMsiTh = 0.03;
2163 const Float_t kMCMcoTh = 0.04;
2165 // The mother volume for the MCMs (air)
2166 const Int_t kNparMCM = 3;
2167 Float_t parMCM[kNparMCM];
2168 parMCM[0] = kMCMx /2.0;
2169 parMCM[1] = kMCMy /2.0;
2170 parMCM[2] = kMCMz /2.0;
2171 gMC->Gsvolu("UMCM","BOX",idtmed[1302-1],parMCM,kNparMCM);
2173 // The MCM carrier G10 layer
2174 parMCM[0] = kMCMx /2.0;
2175 parMCM[1] = kMCMy /2.0;
2176 parMCM[2] = kMCMpcTh/2.0;
2177 gMC->Gsvolu("UMC1","BOX",idtmed[1319-1],parMCM,kNparMCM);
2178 // The MCM carrier Cu layer
2179 parMCM[0] = kMCMx /2.0;
2180 parMCM[1] = kMCMy /2.0;
2181 parMCM[2] = kMCMcuTh/2.0;
2182 gMC->Gsvolu("UMC2","BOX",idtmed[1318-1],parMCM,kNparMCM);
2183 // The silicon of the chips
2184 parMCM[0] = kMCMx /2.0;
2185 parMCM[1] = kMCMy /2.0;
2186 parMCM[2] = kMCMsiTh/2.0;
2187 gMC->Gsvolu("UMC3","BOX",idtmed[1320-1],parMCM,kNparMCM);
2188 // The aluminum of the cooling plates
2189 parMCM[0] = kMCMx /2.0;
2190 parMCM[1] = kMCMy /2.0;
2191 parMCM[2] = kMCMcoTh/2.0;
2192 gMC->Gsvolu("UMC4","BOX",idtmed[1324-1],parMCM,kNparMCM);
2194 // Put the MCM material inside the MCM mother volume
2197 zpos = -kMCMz /2.0 + kMCMpcTh/2.0;
2198 gMC->Gspos("UMC1",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
2199 zpos += kMCMpcTh/2.0 + kMCMcuTh/2.0;
2200 gMC->Gspos("UMC2",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
2201 zpos += kMCMcuTh/2.0 + kMCMsiTh/2.0;
2202 gMC->Gspos("UMC3",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
2203 zpos += kMCMsiTh/2.0 + kMCMcoTh/2.0;
2204 gMC->Gspos("UMC4",1,"UMCM",xpos,ypos,zpos,0,"ONLY");
2206 // Position the MCMs in the mother volume
2207 for (istack = 0; istack < kNstack; istack++) {
2208 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2209 Int_t iDet = GetDetectorSec(ilayer,istack);
2210 Int_t iCopy = GetDetector(ilayer,istack,0) * 1000;
2211 Int_t nMCMrow = GetRowMax(ilayer,istack,0);
2212 Float_t ySize = (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2213 / ((Float_t) nMCMrow);
2215 Float_t xSize = (GetChamberWidth(ilayer) - 2.0*fgkCpadW)
2216 / ((Float_t) nMCMcol + 6); // Introduce 6 gaps
2217 Int_t iMCM[8] = { 1, 2, 3, 5, 8, 9, 10, 12 }; // 0..7 MCM + 6 gap structure
2218 snprintf(cTagV,kTag,"UU%02d",iDet);
2219 for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
2220 for (Int_t iMCMcol = 0; iMCMcol < nMCMcol; iMCMcol++) {
2221 xpos = (0.5 + iMCM[iMCMcol]) * xSize + 1.0
2222 - fgkCwidth[ilayer]/2.0;
2223 ypos = (0.5 + iMCMrow) * ySize + 1.0
2224 - fgkClength[ilayer][istack]/2.0 + fgkHspace/2.0;
2225 zpos = -0.4 + 0.742/2.0;
2226 gMC->Gspos("UMCM",iCopy+iMCMrow*10+iMCMcol,cTagV
2227 ,xpos,ypos,zpos,0,"ONLY");
2228 // Add two additional smaller cooling pipes on top of the MCMs
2229 // to mimic the meandering structure
2230 xpos = (0.5 + iMCM[iMCMcol]) * xSize + 1.0
2231 - fgkCwidth[ilayer]/2.0;
2232 ypos = (0.5 + iMCMrow) * ySize
2233 - fgkClength[ilayer][istack]/2.0 + fgkHspace/2.0;
2234 zpos = 0.0 + 0.742/2.0;
2236 parTube[1] = 0.3/2.0; // Thickness of the cooling pipes
2237 parTube[2] = kMCMx/2.0;
2238 gMC->Gsposp("UTCP",iCopy+iMCMrow*10+iMCMcol+ 50,cTagV
2240 ,matrix[2],"ONLY",parTube,kNparTube);
2241 gMC->Gsposp("UTCP",iCopy+iMCMrow*10+iMCMcol+500,cTagV
2243 ,matrix[2],"ONLY",parTube,kNparTube);
2255 const Float_t kDCSx = 9.0;
2256 const Float_t kDCSy = 14.5;
2257 const Float_t kDCSz = 0.3;
2259 const Float_t kDCSpcTh = 0.15;
2260 const Float_t kDCScuTh = 0.01;
2261 const Float_t kDCScoTh = 0.04;
2263 // The mother volume for the DCSs (air)
2264 const Int_t kNparDCS = 3;
2265 Float_t parDCS[kNparDCS];
2266 parDCS[0] = kDCSx /2.0;
2267 parDCS[1] = kDCSy /2.0;
2268 parDCS[2] = kDCSz /2.0;
2269 gMC->Gsvolu("UDCS","BOX",idtmed[1302-1],parDCS,kNparDCS);
2271 // The DCS carrier G10 layer
2272 parDCS[0] = kDCSx /2.0;
2273 parDCS[1] = kDCSy /2.0;
2274 parDCS[2] = kDCSpcTh/2.0;
2275 gMC->Gsvolu("UDC1","BOX",idtmed[1319-1],parDCS,kNparDCS);
2276 // The DCS carrier Cu layer
2277 parDCS[0] = kDCSx /2.0;
2278 parDCS[1] = kDCSy /2.0;
2279 parDCS[2] = kDCScuTh/2.0;
2280 gMC->Gsvolu("UDC2","BOX",idtmed[1318-1],parDCS,kNparDCS);
2281 // The aluminum of the cooling plates
2282 parDCS[0] = 5.0 /2.0;
2283 parDCS[1] = 5.0 /2.0;
2284 parDCS[2] = kDCScoTh/2.0;
2285 gMC->Gsvolu("UDC3","BOX",idtmed[1324-1],parDCS,kNparDCS);
2287 // Put the DCS material inside the DCS mother volume
2290 zpos = -kDCSz /2.0 + kDCSpcTh/2.0;
2291 gMC->Gspos("UDC1",1,"UDCS",xpos,ypos,zpos,0,"ONLY");
2292 zpos += kDCSpcTh/2.0 + kDCScuTh/2.0;
2293 gMC->Gspos("UDC2",1,"UDCS",xpos,ypos,zpos,0,"ONLY");
2294 zpos += kDCScuTh/2.0 + kDCScoTh/2.0;
2295 gMC->Gspos("UDC3",1,"UDCS",xpos,ypos,zpos,0,"ONLY");
2297 // Put the DCS board in the chamber services mother volume
2298 for (istack = 0; istack < kNstack; istack++) {
2299 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2300 Int_t iDet = GetDetectorSec(ilayer,istack);
2301 Int_t iCopy = iDet + 1;
2302 xpos = fgkCwidth[ilayer]/2.0 - 1.9 * (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2303 / ((Float_t) GetRowMax(ilayer,istack,0));
2304 ypos = 0.05 * fgkClength[ilayer][istack];
2305 zpos = kDCSz/2.0 - fgkCsvH/2.0;
2306 snprintf(cTagV,kTag,"UU%02d",iDet);
2307 gMC->Gspos("UDCS",iCopy,cTagV,xpos,ypos,zpos,0,"ONLY");
2315 const Float_t kORIx = 4.2;
2316 const Float_t kORIy = 13.5;
2317 const Float_t kORIz = 0.3;
2319 const Float_t kORIpcTh = 0.15;
2320 const Float_t kORIcuTh = 0.01;
2321 const Float_t kORIcoTh = 0.04;
2323 // The mother volume for the ORIs (air)
2324 const Int_t kNparORI = 3;
2325 Float_t parORI[kNparORI];
2326 parORI[0] = kORIx /2.0;
2327 parORI[1] = kORIy /2.0;
2328 parORI[2] = kORIz /2.0;
2329 gMC->Gsvolu("UORI","BOX",idtmed[1302-1],parORI,kNparORI);
2331 // The ORI carrier G10 layer
2332 parORI[0] = kORIx /2.0;
2333 parORI[1] = kORIy /2.0;
2334 parORI[2] = kORIpcTh/2.0;
2335 gMC->Gsvolu("UOR1","BOX",idtmed[1319-1],parORI,kNparORI);
2336 // The ORI carrier Cu layer
2337 parORI[0] = kORIx /2.0;
2338 parORI[1] = kORIy /2.0;
2339 parORI[2] = kORIcuTh/2.0;
2340 gMC->Gsvolu("UOR2","BOX",idtmed[1318-1],parORI,kNparORI);
2341 // The aluminum of the cooling plates
2342 parORI[0] = kORIx /2.0;
2343 parORI[1] = kORIy /2.0;
2344 parORI[2] = kORIcoTh/2.0;
2345 gMC->Gsvolu("UOR3","BOX",idtmed[1324-1],parORI,kNparORI);
2347 // Put the ORI material inside the ORI mother volume
2350 zpos = -kORIz /2.0 + kORIpcTh/2.0;
2351 gMC->Gspos("UOR1",1,"UORI",xpos,ypos,zpos,0,"ONLY");
2352 zpos += kORIpcTh/2.0 + kORIcuTh/2.0;
2353 gMC->Gspos("UOR2",1,"UORI",xpos,ypos,zpos,0,"ONLY");
2354 zpos += kORIcuTh/2.0 + kORIcoTh/2.0;
2355 gMC->Gspos("UOR3",1,"UORI",xpos,ypos,zpos,0,"ONLY");
2357 // Put the ORI board in the chamber services mother volume
2358 for (istack = 0; istack < kNstack; istack++) {
2359 for (ilayer = 0; ilayer < kNlayer; ilayer++) {
2360 Int_t iDet = GetDetectorSec(ilayer,istack);
2361 Int_t iCopy = iDet + 1;
2362 xpos = fgkCwidth[ilayer]/2.0 - 1.92 * (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2363 / ((Float_t) GetRowMax(ilayer,istack,0));
2365 zpos = kORIz/2.0 - fgkCsvH/2.0;
2366 snprintf(cTagV,kTag,"UU%02d",iDet);
2367 gMC->Gspos("UORI",iCopy ,cTagV,xpos,ypos,zpos,0,"ONLY");
2368 xpos = -fgkCwidth[ilayer]/2.0 + 3.8 * (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
2369 / ((Float_t) GetRowMax(ilayer,istack,0));
2371 zpos = kORIz/2.0 - fgkCsvH/2.0;
2372 snprintf(cTagV,kTag,"UU%02d",iDet);
2373 gMC->Gspos("UORI",iCopy+kNdet,cTagV,xpos,ypos,zpos,0,"ONLY");
2378 // Services in front of the super module
2381 // Gas in-/outlet pipes (INOX)
2385 gMC->Gsvolu("UTG3","TUBE",idtmed[1308-1],parTube,0);
2386 // The gas inside the in-/outlet pipes (Xe)
2388 parTube[1] = 1.2/2.0;
2390 gMC->Gsvolu("UTG4","TUBE",idtmed[1309-1],parTube,kNparTube);
2394 gMC->Gspos("UTG4",1,"UTG3",xpos,ypos,zpos,0,"ONLY");
2395 for (ilayer = 0; ilayer < kNlayer-1; ilayer++) {
2397 ypos = fgkClength[ilayer][2]/2.0
2398 + fgkClength[ilayer][1]
2399 + fgkClength[ilayer][0];
2400 zpos = 9.0 - fgkSheight/2.0
2401 + ilayer * (fgkCH + fgkVspace);
2403 parTube[1] = 1.5/2.0;
2404 parTube[2] = fgkCwidth[ilayer]/2.0 - 2.5;
2405 gMC->Gsposp("UTG3",ilayer+1 ,"UTI1", xpos, ypos, zpos
2406 ,matrix[2],"ONLY",parTube,kNparTube);
2407 gMC->Gsposp("UTG3",ilayer+1+1*kNlayer,"UTI1", xpos,-ypos, zpos
2408 ,matrix[2],"ONLY",parTube,kNparTube);
2409 gMC->Gsposp("UTG3",ilayer+1+2*kNlayer,"UTI2", xpos, ypos, zpos
2410 ,matrix[2],"ONLY",parTube,kNparTube);
2411 gMC->Gsposp("UTG3",ilayer+1+3*kNlayer,"UTI2", xpos,-ypos, zpos
2412 ,matrix[2],"ONLY",parTube,kNparTube);
2413 gMC->Gsposp("UTG3",ilayer+1+4*kNlayer,"UTI3", xpos, ypos, zpos
2414 ,matrix[2],"ONLY",parTube,kNparTube);
2415 gMC->Gsposp("UTG3",ilayer+1+5*kNlayer,"UTI3", xpos,-ypos, zpos
2416 ,matrix[2],"ONLY",parTube,kNparTube);
2419 // Gas distribution box
2420 parBox[0] = 14.50/2.0;
2421 parBox[1] = 4.52/2.0;
2422 parBox[2] = 5.00/2.0;
2423 gMC->Gsvolu("UTGD","BOX ",idtmed[1308-1],parBox,kNparBox);
2424 parBox[0] = 14.50/2.0;
2425 parBox[1] = 4.00/2.0;
2426 parBox[2] = 4.40/2.0;
2427 gMC->Gsvolu("UTGI","BOX ",idtmed[1309-1],parBox,kNparBox);
2429 parTube[1] = 4.0/2.0;
2430 parTube[2] = 8.0/2.0;
2431 gMC->Gsvolu("UTGT","TUBE",idtmed[1308-1],parTube,kNparTube);
2433 parTube[1] = 3.4/2.0;
2434 parTube[2] = 8.0/2.0;
2435 gMC->Gsvolu("UTGG","TUBE",idtmed[1309-1],parTube,kNparTube);
2439 gMC->Gspos("UTGI",1,"UTGD",xpos,ypos,zpos, 0,"ONLY");
2440 gMC->Gspos("UTGG",1,"UTGT",xpos,ypos,zpos, 0,"ONLY");
2444 gMC->Gspos("UTGD",1,"UTF1",xpos,ypos,zpos, 0,"ONLY");
2448 gMC->Gspos("UTGT",1,"UTF1",xpos,ypos,zpos, 0,"ONLY");
2452 gMC->Gspos("UTGT",3,"UTF1",xpos,ypos,zpos,matrix[2],"ONLY");
2456 gMC->Gspos("UTGT",5,"UTF1",xpos,ypos,zpos,matrix[2],"ONLY");
2458 // Cooling manifolds
2459 parBox[0] = 5.0/2.0;
2460 parBox[1] = 23.0/2.0;
2461 parBox[2] = 70.0/2.0;
2462 gMC->Gsvolu("UTCM","BOX ",idtmed[1302-1],parBox,kNparBox);
2463 parBox[0] = 5.0/2.0;
2464 parBox[1] = 5.0/2.0;
2465 parBox[2] = 70.0/2.0;
2466 gMC->Gsvolu("UTCA","BOX ",idtmed[1308-1],parBox,kNparBox);
2467 parBox[0] = 5.0/2.0 - 0.3;
2468 parBox[1] = 5.0/2.0 - 0.3;
2469 parBox[2] = 70.0/2.0 - 0.3;
2470 gMC->Gsvolu("UTCW","BOX ",idtmed[1314-1],parBox,kNparBox);
2474 gMC->Gspos("UTCW",1,"UTCA", xpos, ypos, zpos, 0,"ONLY");
2476 ypos = 5.0/2.0 - 23.0/2.0;
2478 gMC->Gspos("UTCA",1,"UTCM", xpos, ypos, zpos, 0,"ONLY");
2480 parTube[1] = 3.0/2.0;
2481 parTube[2] = 18.0/2.0;
2482 gMC->Gsvolu("UTCO","TUBE",idtmed[1308-1],parTube,kNparTube);
2484 parTube[1] = 3.0/2.0 - 0.3;
2485 parTube[2] = 18.0/2.0;
2486 gMC->Gsvolu("UTCL","TUBE",idtmed[1314-1],parTube,kNparTube);
2490 gMC->Gspos("UTCL",1,"UTCO", xpos, ypos, zpos, 0,"ONLY");
2493 zpos = -70.0/2.0 + 7.0;
2494 gMC->Gspos("UTCO",1,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2496 gMC->Gspos("UTCO",2,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2498 gMC->Gspos("UTCO",3,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2500 gMC->Gspos("UTCO",4,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2502 gMC->Gspos("UTCO",5,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2504 gMC->Gspos("UTCO",6,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2506 gMC->Gspos("UTCO",7,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2508 gMC->Gspos("UTCO",8,"UTCM", xpos, ypos, zpos,matrix[4],"ONLY");
2511 ypos = fgkFlength/2.0 - 23.0/2.0;
2513 gMC->Gspos("UTCM",1,"UTF1", xpos, ypos, zpos,matrix[0],"ONLY");
2514 gMC->Gspos("UTCM",2,"UTF1",-xpos, ypos, zpos,matrix[1],"ONLY");
2515 gMC->Gspos("UTCM",3,"UTF2", xpos,-ypos, zpos,matrix[5],"ONLY");
2516 gMC->Gspos("UTCM",4,"UTF2",-xpos,-ypos, zpos,matrix[6],"ONLY");
2518 // Power connection boards (Cu)
2519 parBox[0] = 0.5/2.0;
2520 parBox[1] = 15.0/2.0;
2521 parBox[2] = 7.0/2.0;
2522 gMC->Gsvolu("UTPC","BOX ",idtmed[1325-1],parBox,kNparBox);
2523 for (ilayer = 0; ilayer < kNlayer-1; ilayer++) {
2524 xpos = fgkCwidth[ilayer]/2.0 + kPWRwid/2.0;
2526 zpos = fgkVrocsm + fgkSMpltT + kPWRhgtA/2.0 - fgkSheight/2.0 + kPWRposz
2527 + (ilayer+1) * (fgkCH + fgkVspace);
2528 gMC->Gspos("UTPC",ilayer ,"UTF1", xpos,ypos,zpos,matrix[0],"ONLY");
2529 gMC->Gspos("UTPC",ilayer+kNlayer,"UTF1",-xpos,ypos,zpos,matrix[1],"ONLY");
2531 xpos = fgkCwidth[5]/2.0 + kPWRhgtA/2.0 - 2.0;
2533 zpos = fgkSheight/2.0 - fgkSMpltT - 2.0;
2534 gMC->Gspos("UTPC",5 ,"UTF1", xpos,ypos,zpos,matrix[3],"ONLY");
2535 gMC->Gspos("UTPC",5+kNlayer,"UTF1",-xpos,ypos,zpos,matrix[3],"ONLY");
2537 // Power connection panel (Al)
2538 parBox[0] = 60.0/2.0;
2539 parBox[1] = 10.0/2.0;
2540 parBox[2] = 3.0/2.0;
2541 gMC->Gsvolu("UTPP","BOX ",idtmed[1301-1],parBox,kNparBox);
2545 gMC->Gspos("UTPP",1,"UTF1", xpos,ypos,zpos,0,"ONLY");
2548 // Electronics boxes
2552 parBox[0] = 60.0/2.0;
2553 parBox[1] = 10.0/2.0;
2554 parBox[2] = 6.0/2.0;
2555 gMC->Gsvolu("UTE1","BOX ",idtmed[1308-1],parBox,kNparBox);
2557 parBox[0] = parBox[0] - 0.5;
2558 parBox[1] = parBox[1] - 0.5;
2559 parBox[2] = parBox[2] - 0.5;
2560 gMC->Gsvolu("UTE2","BOX ",idtmed[1302-1],parBox,kNparBox);
2564 gMC->Gspos("UTE2",1,"UTE1",xpos,ypos,zpos,0,"ONLY");
2566 ypos = fgkSlength/2.0 - 10.0/2.0 - 3.0;
2567 zpos = -fgkSheight/2.0 + 6.0/2.0 + 1.0;
2568 gMC->Gspos("UTE1",1,"UTI1", xpos,ypos,zpos,0,"ONLY");
2569 gMC->Gspos("UTE1",2,"UTI2", xpos,ypos,zpos,0,"ONLY");
2570 gMC->Gspos("UTE1",3,"UTI3", xpos,ypos,zpos,0,"ONLY");
2573 parBox[0] = 50.0/2.0;
2574 parBox[1] = 15.0/2.0;
2575 parBox[2] = 20.0/2.0;
2576 gMC->Gsvolu("UTE3","BOX ",idtmed[1308-1],parBox,kNparBox);
2578 parBox[0] = parBox[0] - 0.5;
2579 parBox[1] = parBox[1] - 0.5;
2580 parBox[2] = parBox[2] - 0.5;
2581 gMC->Gsvolu("UTE4","BOX ",idtmed[1302-1],parBox,kNparBox);
2585 gMC->Gspos("UTE4",1,"UTE3",xpos,ypos,zpos,0,"ONLY");
2587 ypos = -fgkSlength/2.0 + 15.0/2.0 + 3.0;
2588 zpos = -fgkSheight/2.0 + 20.0/2.0 + 1.0;
2589 gMC->Gspos("UTE3",1,"UTI1", xpos,ypos,zpos,0,"ONLY");
2590 gMC->Gspos("UTE3",2,"UTI2", xpos,ypos,zpos,0,"ONLY");
2591 gMC->Gspos("UTE3",3,"UTI3", xpos,ypos,zpos,0,"ONLY");
2594 parBox[0] = 20.0/2.0;
2595 parBox[1] = 7.0/2.0;
2596 parBox[2] = 20.0/2.0;
2597 gMC->Gsvolu("UTE5","BOX ",idtmed[1308-1],parBox,kNparBox);
2599 parBox[0] = parBox[0] - 0.5;
2600 parBox[1] = parBox[1] - 0.5;
2601 parBox[2] = parBox[2] - 0.5;
2602 gMC->Gsvolu("UTE6","BOX ",idtmed[1302-1],parBox,kNparBox);
2606 gMC->Gspos("UTE6",1,"UTE5",xpos,ypos,zpos,0,"ONLY");
2608 ypos = -fgkSlength/2.0 + 7.0/2.0 + 3.0;
2610 gMC->Gspos("UTE5",1,"UTI1", xpos,ypos,zpos,0,"ONLY");
2611 gMC->Gspos("UTE5",2,"UTI2", xpos,ypos,zpos,0,"ONLY");
2612 gMC->Gspos("UTE5",3,"UTI3", xpos,ypos,zpos,0,"ONLY");
2614 gMC->Gspos("UTE5",4,"UTI1", xpos,ypos,zpos,0,"ONLY");
2615 gMC->Gspos("UTE5",5,"UTI2", xpos,ypos,zpos,0,"ONLY");
2616 gMC->Gspos("UTE5",6,"UTI3", xpos,ypos,zpos,0,"ONLY");
2620 //_____________________________________________________________________________
2621 void AliTRDgeometry::AssembleChamber(Int_t ilayer, Int_t istack)
2624 // Group volumes UA, UD, UF, UU into an assembly that defines the
2625 // alignable volume of a single readout chamber
2628 const Int_t kTag = 100;
2632 Double_t xpos = 0.0;
2633 Double_t ypos = 0.0;
2634 Double_t zpos = 0.0;
2636 Int_t idet = GetDetectorSec(ilayer,istack);
2638 // Create the assembly for a given ROC
2639 snprintf(cTagM,kTag,"UT%02d",idet);
2640 TGeoVolume *roc = new TGeoVolumeAssembly(cTagM);
2642 // Add the lower part of the chamber (aluminum frame),
2643 // including radiator and drift region
2646 zpos = fgkCraH/2.0 + fgkCdrH/2.0 - fgkCHsv/2.0;
2647 snprintf(cTagV,kTag,"UA%02d",idet);
2648 TGeoVolume *rocA = gGeoManager->GetVolume(cTagV);
2649 roc->AddNode(rocA,1,new TGeoTranslation(xpos,ypos,zpos));
2651 // Add the additional aluminum ledges
2652 xpos = fgkCwidth[ilayer]/2.0 + fgkCalWmod/2.0;
2654 zpos = fgkCraH + fgkCdrH - fgkCalZpos - fgkCalHmod/2.0 - fgkCHsv/2.0;
2655 snprintf(cTagV,kTag,"UZ%02d",idet);
2656 TGeoVolume *rocZ = gGeoManager->GetVolume(cTagV);
2657 roc->AddNode(rocZ,1,new TGeoTranslation( xpos,ypos,zpos));
2658 roc->AddNode(rocZ,2,new TGeoTranslation(-xpos,ypos,zpos));
2660 // Add the additional wacosit ledges
2661 xpos = fgkCwidth[ilayer]/2.0 + fgkCwsW/2.0;
2663 zpos = fgkCraH + fgkCdrH - fgkCwsH/2.0 - fgkCHsv/2.0;
2664 snprintf(cTagV,kTag,"UP%02d",idet);
2665 TGeoVolume *rocP = gGeoManager->GetVolume(cTagV);
2666 roc->AddNode(rocP,1,new TGeoTranslation( xpos,ypos,zpos));
2667 roc->AddNode(rocP,2,new TGeoTranslation(-xpos,ypos,zpos));
2669 // Add the middle part of the chamber (G10 frame),
2670 // including amplification region
2673 zpos = fgkCamH/2.0 + fgkCraH + fgkCdrH - fgkCHsv/2.0;
2674 snprintf(cTagV,kTag,"UD%02d",idet);
2675 TGeoVolume *rocD = gGeoManager->GetVolume(cTagV);
2676 roc->AddNode(rocD,1,new TGeoTranslation(xpos,ypos,zpos));
2678 // Add the upper part of the chamber (aluminum frame),
2679 // including back panel and FEE
2682 zpos = fgkCroH/2.0 + fgkCamH + fgkCraH + fgkCdrH - fgkCHsv/2.0;
2683 snprintf(cTagV,kTag,"UF%02d",idet);
2684 TGeoVolume *rocF = gGeoManager->GetVolume(cTagV);
2685 roc->AddNode(rocF,1,new TGeoTranslation(xpos,ypos,zpos));
2687 // Add the volume with services on top of the back panel
2690 zpos = fgkCsvH/2.0 + fgkCroH + fgkCamH + fgkCraH + fgkCdrH - fgkCHsv/2.0;
2691 snprintf(cTagV,kTag,"UU%02d",idet);
2692 TGeoVolume *rocU = gGeoManager->GetVolume(cTagV);
2693 roc->AddNode(rocU,1,new TGeoTranslation(xpos,ypos,zpos));
2695 // Place the ROC assembly into the super modules
2698 ypos = fgkClength[ilayer][0] + fgkClength[ilayer][1] + fgkClength[ilayer][2]/2.0;
2699 for (Int_t ic = 0; ic < istack; ic++) {
2700 ypos -= fgkClength[ilayer][ic];
2702 ypos -= fgkClength[ilayer][istack]/2.0;
2703 zpos = fgkVrocsm + fgkSMpltT + fgkCHsv/2.0 - fgkSheight/2.0
2704 + ilayer * (fgkCH + fgkVspace);
2705 TGeoVolume *sm1 = gGeoManager->GetVolume("UTI1");
2706 TGeoVolume *sm2 = gGeoManager->GetVolume("UTI2");
2707 TGeoVolume *sm3 = gGeoManager->GetVolume("UTI3");
2708 sm1->AddNode(roc,1,new TGeoTranslation(xpos,ypos,zpos));
2709 sm2->AddNode(roc,1,new TGeoTranslation(xpos,ypos,zpos));
2712 sm3->AddNode(roc,1,new TGeoTranslation(xpos,ypos,zpos));
2717 //_____________________________________________________________________________
2718 Bool_t AliTRDgeometry::RotateBack(Int_t det
2719 , const Double_t * const loc
2720 , Double_t *glb) const
2723 // Rotates a chambers to transform the corresponding local frame
2724 // coordinates <loc> into the coordinates of the ALICE restframe <glb>.
2727 Int_t sector = GetSector(det);
2728 Float_t phi = 2.0 * TMath::Pi() / (Float_t) fgkNsector * ((Float_t) sector + 0.5);
2730 glb[0] = loc[0] * TMath::Cos(phi) - loc[1] * TMath::Sin(phi);
2731 glb[1] = loc[0] * TMath::Sin(phi) + loc[1] * TMath::Cos(phi);
2738 //_____________________________________________________________________________
2739 Int_t AliTRDgeometry::GetDetectorSec(Int_t layer, Int_t stack)
2742 // Convert plane / stack into detector number for one single sector
2745 return (layer + stack * fgkNlayer);
2749 //_____________________________________________________________________________
2750 Int_t AliTRDgeometry::GetDetector(Int_t layer, Int_t stack, Int_t sector)
2753 // Convert layer / stack / sector into detector number
2756 return (layer + stack * fgkNlayer + sector * fgkNlayer * fgkNstack);
2760 //_____________________________________________________________________________
2761 Int_t AliTRDgeometry::GetLayer(Int_t det)
2764 // Reconstruct the layer number from the detector number
2767 return ((Int_t) (det % fgkNlayer));
2771 //_____________________________________________________________________________
2772 Int_t AliTRDgeometry::GetStack(Int_t det)
2775 // Reconstruct the stack number from the detector number
2778 return ((Int_t) (det % (fgkNlayer * fgkNstack)) / fgkNlayer);
2782 //_____________________________________________________________________________
2783 Int_t AliTRDgeometry::GetStack(Double_t z, Int_t layer)
2786 // Reconstruct the chamber number from the z position and layer number
2788 // The return function has to be protected for positiveness !!
2792 (layer >= fgkNlayer)) return -1;
2794 Int_t istck = fgkNstack;
2795 Double_t zmin = 0.0;
2796 Double_t zmax = 0.0;
2800 if (istck < 0) break;
2801 AliTRDpadPlane *pp = GetPadPlane(layer,istck);
2802 zmax = pp->GetRow0();
2803 Int_t nrows = pp->GetNrows();
2804 zmin = zmax - 2 * pp->GetLengthOPad()
2805 - (nrows-2) * pp->GetLengthIPad()
2806 - (nrows-1) * pp->GetRowSpacing();
2807 } while((z < zmin) || (z > zmax));
2813 //_____________________________________________________________________________
2814 Int_t AliTRDgeometry::GetSector(Int_t det)
2817 // Reconstruct the sector number from the detector number
2820 return ((Int_t) (det / (fgkNlayer * fgkNstack)));
2824 //_____________________________________________________________________________
2825 AliTRDpadPlane *AliTRDgeometry::GetPadPlane(Int_t layer, Int_t stack)
2828 // Returns the pad plane for a given plane <pl> and stack <st> number
2831 if (!fgPadPlaneArray) {
2832 CreatePadPlaneArray();
2835 Int_t ipp = GetDetectorSec(layer,stack);
2836 return ((AliTRDpadPlane *) fgPadPlaneArray->At(ipp));
2840 //_____________________________________________________________________________
2841 Int_t AliTRDgeometry::GetRowMax(Int_t layer, Int_t stack, Int_t /*sector*/)
2844 // Returns the number of rows on the pad plane
2847 return GetPadPlane(layer,stack)->GetNrows();
2851 //_____________________________________________________________________________
2852 Int_t AliTRDgeometry::GetColMax(Int_t layer)
2855 // Returns the number of rows on the pad plane
2858 return GetPadPlane(layer,0)->GetNcols();
2862 //_____________________________________________________________________________
2863 Double_t AliTRDgeometry::GetRow0(Int_t layer, Int_t stack, Int_t /*sector*/)
2866 // Returns the position of the border of the first pad in a row
2869 return GetPadPlane(layer,stack)->GetRow0();
2873 //_____________________________________________________________________________
2874 Double_t AliTRDgeometry::GetCol0(Int_t layer)
2877 // Returns the position of the border of the first pad in a column
2880 return GetPadPlane(layer,0)->GetCol0();
2884 //_____________________________________________________________________________
2885 Bool_t AliTRDgeometry::CreateClusterMatrixArray()
2888 // Create the matrices to transform cluster coordinates from the
2889 // local chamber system to the tracking coordinate system
2896 if(fgClusterMatrixArray)
2900 TString vpStr = "ALIC_1/B077_1/BSEGMO";
2901 TString vpApp1 = "_1/BTRD";
2902 TString vpApp2 = "_1";
2903 TString vpApp3a = "/UTR1_1/UTS1_1/UTI1_1";
2904 TString vpApp3b = "/UTR2_1/UTS2_1/UTI2_1";
2905 TString vpApp3c = "/UTR3_1/UTS3_1/UTI3_1";
2907 fgClusterMatrixArray = new TObjArray(kNdet);
2908 AliAlignObjParams o;
2910 for (Int_t iLayer = AliGeomManager::kTRD1; iLayer <= AliGeomManager::kTRD6; iLayer++) {
2911 for (Int_t iModule = 0; iModule < AliGeomManager::LayerSize(iLayer); iModule++) {
2913 Int_t isector = iModule/Nstack();
2914 Int_t istack = iModule%Nstack();
2915 Int_t iLayerTRD = iLayer - AliGeomManager::kTRD1;
2916 Int_t lid = GetDetector(iLayerTRD,istack,isector);
2918 // Check for disabled supermodules
2928 // Check for holes in from of PHOS
2941 if (!gGeoManager->CheckPath(volPath)) {
2945 UShort_t volid = AliGeomManager::LayerToVolUID(iLayer,iModule);
2946 const char *symname = AliGeomManager::SymName(volid);
2947 TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(symname);
2948 const char *path = symname;
2950 path = pne->GetTitle();
2955 if (!strstr(path,"ALIC")) {
2956 AliDebugClass(1,Form("Not a valid path: %s\n",path));
2959 if (!gGeoManager->cd(path)) {
2960 AliErrorClass(Form("Cannot go to path: %s\n",path));
2963 TGeoHMatrix *m = gGeoManager->GetCurrentMatrix();
2965 TGeoRotation mchange;
2966 mchange.RotateY(90);
2967 mchange.RotateX(90);
2970 // Cluster transformation matrix
2972 TGeoHMatrix rotMatrix(mchange.Inverse());
2973 rotMatrix.MultiplyLeft(m);
2974 Double_t sectorAngle = 20.0 * (isector % 18) + 10.0;
2975 TGeoHMatrix rotSector;
2976 rotSector.RotateZ(sectorAngle);
2977 rotMatrix.MultiplyLeft(&rotSector.Inverse());
2979 fgClusterMatrixArray->AddAt(new TGeoHMatrix(rotMatrix),lid);
2988 //_____________________________________________________________________________
2989 TGeoHMatrix *AliTRDgeometry::GetClusterMatrix(Int_t det)
2992 // Returns the cluster transformation matrix for a given detector
2995 if (!fgClusterMatrixArray) {
2996 if (!CreateClusterMatrixArray()) {
3000 return (TGeoHMatrix *) fgClusterMatrixArray->At(det);
3004 //_____________________________________________________________________________
3005 Bool_t AliTRDgeometry::ChamberInGeometry(Int_t det)
3008 // Checks whether the given detector is part of the current geometry
3011 if (!GetClusterMatrix(det)) {
3020 //_____________________________________________________________________________
3021 Bool_t AliTRDgeometry::IsHole(Int_t /*la*/, Int_t st, Int_t se) const
3024 // Checks for holes in front of PHOS
3027 if (((se == 13) || (se == 14) || (se == 15)) &&
3036 //_____________________________________________________________________________
3037 Bool_t AliTRDgeometry::IsOnBoundary(Int_t det, Float_t y, Float_t z, Float_t eps) const
3040 // Checks whether position is at the boundary of the sensitive volume
3043 Int_t ly = GetLayer(det);
3045 (ly >= fgkNlayer)) return kTRUE;
3047 Int_t stk = GetStack(det);
3049 (stk >= fgkNstack)) return kTRUE;
3051 AliTRDpadPlane *pp = (AliTRDpadPlane*) fgPadPlaneArray->At(GetDetectorSec(ly, stk));
3052 if(!pp) return kTRUE;
3054 Double_t max = pp->GetRow0();
3055 Int_t n = pp->GetNrows();
3056 Double_t min = max - 2 * pp->GetLengthOPad()
3057 - (n-2) * pp->GetLengthIPad()
3058 - (n-1) * pp->GetRowSpacing();
3059 if(z < min+eps || z > max-eps){
3060 //printf("z : min[%7.2f (%7.2f)] %7.2f max[(%7.2f) %7.2f]\n", min, min+eps, z, max-eps, max);
3063 min = pp->GetCol0();
3065 max = min +2 * pp->GetWidthOPad()
3066 + (n-2) * pp->GetWidthIPad()
3067 + (n-1) * pp->GetColSpacing();
3068 if(y < min+eps || y > max-eps){
3069 //printf("y : min[%7.2f (%7.2f)] %7.2f max[(%7.2f) %7.2f]\n", min, min+eps, y, max-eps, max);