Clean up to correct for the mess introduced by my eratic branching !
[u/mrichter/AliRoot.git] / TRD / AliTRD.cxx
CommitLineData
4c039060 1/**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
3 * *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
6 * *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
15
16/*
17$Log$
94c641ff 18Revision 1.14 1999/11/02 16:57:02 fca
19Avoid non ansi warnings on HP compilers
20
8459a454 21Revision 1.13 1999/11/02 16:35:56 fca
22New version of TRD introduced
23
5c7f4665 24Revision 1.12 1999/11/01 20:41:51 fca
25Added protections against using the wrong version of FRAME
26
ab76897d 27Revision 1.11 1999/09/29 09:24:34 fca
28Introduction of the Copyright and cvs Log
29
4c039060 30*/
31
fe4da5cc 32///////////////////////////////////////////////////////////////////////////////
33// //
34// Transition Radiation Detector //
35// This class contains the basic functions for the Transition Radiation //
5c7f4665 36// Detector, as well as the geometry. //
37// Functions specific to one particular geometry are contained in the //
38// derived classes. //
fe4da5cc 39// //
40//Begin_Html
41/*
1439f98e 42<img src="picts/AliTRDClass.gif">
fe4da5cc 43*/
44//End_Html
45// //
46// //
47///////////////////////////////////////////////////////////////////////////////
48
5c7f4665 49#include <stdlib.h>
50
fe4da5cc 51#include <TMath.h>
fe4da5cc 52#include <TNode.h>
fe4da5cc 53#include <TPGON.h>
54
fe4da5cc 55#include "AliTRD.h"
56#include "AliRun.h"
d3f347ff 57#include "AliConst.h"
fe4da5cc 58
59ClassImp(AliTRD)
60
61//_____________________________________________________________________________
62AliTRD::AliTRD()
63{
64 //
65 // Default constructor
66 //
82bbf98a 67
8459a454 68 Int_t iplan;
69
d3f347ff 70 fIshunt = 0;
71 fGasMix = 0;
99d5402e 72 fHits = 0;
73 fDigits = 0;
5c7f4665 74 fHole = 0;
75
76 fClusters = 0;
77 fNclusters = 0;
82bbf98a 78
79 // The chamber dimensions
8459a454 80 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 81 fClengthI[iplan] = 0.;
82 fClengthM1[iplan] = 0.;
83 fClengthM2[iplan] = 0.;
84 fClengthO1[iplan] = 0.;
85 fClengthO2[iplan] = 0.;
86 fClengthO3[iplan] = 0.;
87 fCwidth[iplan] = 0.;
88 }
89
8459a454 90 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 91 for (Int_t icham = 0; icham < kNcham; icham++) {
92 for (Int_t isect = 0; isect < kNsect; isect++) {
93 fRowMax[iplan][icham][isect] = 0;
94 }
95 }
96 fColMax[iplan] = 0;
82bbf98a 97 }
5c7f4665 98 fTimeMax = 0;
99
100 fRowPadSize = 0;
101 fColPadSize = 0;
102 fTimeBinSize = 0;
82bbf98a 103
fe4da5cc 104}
105
106//_____________________________________________________________________________
107AliTRD::AliTRD(const char *name, const char *title)
108 : AliDetector(name,title)
109{
110 //
111 // Standard constructor for the TRD
112 //
113
8459a454 114 Int_t iplan;
115
5c7f4665 116 // Check that FRAME is there otherwise we have no place where to
117 // put TRD
118 AliModule* FRAME=gAlice->GetModule("FRAME");
119 if (!FRAME) {
120 Error("Ctor","TRD needs FRAME to be present\n");
121 exit(1);
122 }
123
124 // Define the TRD geometry according to the FRAME geometry
125 if (FRAME->IsVersion() == 0)
126 // With hole
127 fHole = 1;
128 else
129 // Without hole
130 fHole = 0;
131
fe4da5cc 132 // Allocate the hit array
5c7f4665 133 fHits = new TClonesArray("AliTRDhit" , 405);
99d5402e 134
135 // Allocate the digits array
5c7f4665 136 fDigits = new TClonesArray("AliTRDdigit" ,10000);
137
138 // Allocate the cluster array
139 fClusters = new TClonesArray("AliTRDcluster", 400);
140 fNclusters = 0;
99d5402e 141
82bbf98a 142 fIshunt = 0;
143 fGasMix = 0;
144
145 // The chamber dimensions
8459a454 146 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 147 fClengthI[iplan] = 0.;
148 fClengthM1[iplan] = 0.;
149 fClengthM2[iplan] = 0.;
150 fClengthO1[iplan] = 0.;
151 fClengthO2[iplan] = 0.;
152 fClengthO3[iplan] = 0.;
153 fCwidth[iplan] = 0.;
82bbf98a 154 }
fe4da5cc 155
8459a454 156 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 157 for (Int_t icham = 0; icham < kNcham; icham++) {
158 for (Int_t isect = 0; isect < kNsect; isect++) {
159 fRowMax[iplan][icham][isect] = 0;
160 }
161 }
162 fColMax[iplan] = 0;
163 }
164 fTimeMax = 0;
165
166 fRowPadSize = 0;
167 fColPadSize = 0;
168 fTimeBinSize = 0;
169
fe4da5cc 170 SetMarkerColor(kWhite);
82bbf98a 171
fe4da5cc 172}
99d5402e 173
174//_____________________________________________________________________________
175AliTRD::~AliTRD()
176{
177 //
178 // TRD destructor
179 //
180
181 fIshunt = 0;
182
183 delete fHits;
184 delete fDigits;
5c7f4665 185 delete fClusters;
186
187}
188
189//_____________________________________________________________________________
190void AliTRD::AddCluster(Int_t *tracks, Int_t *clusters, Float_t *position)
191{
192 //
193 // Add a cluster for the TRD
194 //
195
196 TClonesArray &lclusters = *fClusters;
197 new(lclusters[fNclusters++]) AliTRDcluster(tracks,clusters,position);
99d5402e 198
199}
200
201//_____________________________________________________________________________
202void AliTRD::AddDigit(Int_t *tracks, Int_t *digits)
203{
204 //
205 // Add a digit for the TRD
206 //
207
208 TClonesArray &ldigits = *fDigits;
209 new(ldigits[fNdigits++]) AliTRDdigit(tracks,digits);
210
211}
212
fe4da5cc 213//_____________________________________________________________________________
214void AliTRD::AddHit(Int_t track, Int_t *vol, Float_t *hits)
215{
216 //
217 // Add a hit for the TRD
218 //
82bbf98a 219
fe4da5cc 220 TClonesArray &lhits = *fHits;
221 new(lhits[fNhits++]) AliTRDhit(fIshunt,track,vol,hits);
82bbf98a 222
fe4da5cc 223}
224
225//_____________________________________________________________________________
226void AliTRD::BuildGeometry()
227{
228 //
229 // Create the ROOT TNode geometry for the TRD
230 //
82bbf98a 231
fe4da5cc 232 TNode *Node, *Top;
233 TPGON *pgon;
234 const Int_t kColorTRD = 46;
d3f347ff 235
fe4da5cc 236 // Find the top node alice
82bbf98a 237 Top = gAlice->GetGeometry()->GetNode("alice");
d3f347ff 238
82bbf98a 239 pgon = new TPGON("S_TRD","TRD","void",0,360,kNsect,4);
240 Float_t ff = TMath::Cos(kDegrad * 180 / kNsect);
241 Float_t rrmin = kRmin / ff;
242 Float_t rrmax = kRmax / ff;
243 pgon->DefineSection(0,-kZmax1,rrmax,rrmax);
244 pgon->DefineSection(1,-kZmax2,rrmin,rrmax);
245 pgon->DefineSection(2, kZmax2,rrmin,rrmax);
246 pgon->DefineSection(3, kZmax1,rrmax,rrmax);
fe4da5cc 247 Top->cd();
248 Node = new TNode("TRD","TRD","S_TRD",0,0,0,"");
249 Node->SetLineColor(kColorTRD);
250 fNodes->Add(Node);
d3f347ff 251
fe4da5cc 252}
253
254//_____________________________________________________________________________
82bbf98a 255void AliTRD::CreateGeometry()
fe4da5cc 256{
82bbf98a 257 //
258 // Creates the volumes for the TRD chambers
259 //
260 // Author: Christoph Blume (C.Blume@gsi.de) 20/07/99
261 //
262 // The volumes:
5c7f4665 263 // TRD1-3 (Air) --- The TRD mother volumes for one sector.
82bbf98a 264 // To be placed into the spaceframe.
265 //
266 // UAFI(/M/O) (Al) --- The aluminum frame of the inner(/middle/outer) chambers (readout)
267 // UCFI(/M/O) (C) --- The carbon frame of the inner(/middle/outer) chambers
268 // (driftchamber + radiator)
269 // UAII(/M/O) (Air) --- The inner part of the readout of the inner(/middle/outer) chambers
270 // UFII(/M/O) (Air) --- The inner part of the chamner and radiator of the
271 // inner(/middle/outer) chambers
272 //
273 // The material layers in one chamber:
274 // UL01 (G10) --- The gas seal of the radiator
275 // UL02 (CO2) --- The gas in the radiator
276 // UL03 (PE) --- The foil stack
277 // UL04 (Mylar) --- Entrance window to the driftvolume and HV-cathode
278 // UL05 (Xe) --- The driftvolume
279 // UL06 (Xe) --- The amplification region
280 //
281 // UL07 (Cu) --- The pad plane
282 // UL08 (G10) --- The Nomex honeycomb support structure
283 // UL09 (Cu) --- FEE and signal lines
284 // UL10 (PE) --- The cooling devices
285 // UL11 (Water) --- The cooling water
286
287 // Check that FRAME is there otherwise we have no place where to put the TRD
288 AliModule* FRAME = gAlice->GetModule("FRAME");
289 if (!FRAME) return;
290
8459a454 291 Int_t iplan;
292
82bbf98a 293 const Int_t npar_trd = 4;
294 const Int_t npar_cha = 3;
295
296 Float_t par_dum[3];
297 Float_t par_trd[npar_trd];
298 Float_t par_cha[npar_cha];
299
300 Float_t xpos, ypos, zpos;
301
5c7f4665 302 Int_t *idtmed = fIdtmed->GetArray() - 1299;
82bbf98a 303
304 // The length of the inner chambers
8459a454 305 for (iplan = 0; iplan < kNplan; iplan++)
5c7f4665 306 fClengthI[iplan] = 110.0;
307
82bbf98a 308 // The length of the middle chambers
5c7f4665 309 fClengthM1[0] = 123.5;
310 fClengthM1[1] = 131.0;
311 fClengthM1[2] = 138.5;
312 fClengthM1[3] = 146.0;
313 fClengthM1[4] = 153.0;
314 fClengthM1[5] = 160.5;
315
316 fClengthM2[0] = 123.5 - 7.0;
317 fClengthM2[1] = 131.0 - 7.0;
318 fClengthM2[2] = 138.5 - 7.0;
319 fClengthM2[3] = 146.0 - 7.0;
320 fClengthM2[4] = 153.0 - 7.0;
321 fClengthM2[5] = 160.4 - 7.0;
322
82bbf98a 323 // The length of the outer chambers
5c7f4665 324 fClengthO1[0] = 123.5;
325 fClengthO1[1] = 131.0;
326 fClengthO1[2] = 134.5;
327 fClengthO1[3] = 142.0;
328 fClengthO1[4] = 142.0;
329 fClengthO1[5] = 134.5;
330
331 fClengthO2[0] = 123.5;
332 fClengthO2[1] = 131.0;
333 fClengthO2[2] = 134.5;
334 fClengthO2[3] = 142.0;
335 fClengthO2[4] = 142.0;
336 fClengthO2[5] = 134.5;
337
338 fClengthO3[0] = 86.5;
339 fClengthO3[1] = 101.5;
340 fClengthO3[2] = 112.5;
341 fClengthO3[3] = 127.5;
342 fClengthO3[4] = 134.5;
343 fClengthO3[5] = 134.5;
82bbf98a 344
345 // The width of the chambers
5c7f4665 346 fCwidth[0] = 99.6;
347 fCwidth[1] = 104.1;
348 fCwidth[2] = 108.5;
349 fCwidth[3] = 112.9;
350 fCwidth[4] = 117.4;
351 fCwidth[5] = 121.8;
352
353 // The TRD mother volume for one sector (Air) (dimensions identical to BTR1)
82bbf98a 354 par_trd[0] = kSwidth1/2.;
355 par_trd[1] = kSwidth2/2.;
5c7f4665 356 par_trd[2] = kSlenTR1/2.;
82bbf98a 357 par_trd[3] = kSheight/2.;
5c7f4665 358 gMC->Gsvolu("TRD1","TRD1",idtmed[1302-1],par_trd,npar_trd);
359
360 // The TRD mother volume for one sector (Air) (dimensions identical to BTR2 + BTR3).
361 // Only used for the geometry with holes.
362 if (fHole) {
363
364 par_trd[0] = kSwidth1/2.;
365 par_trd[1] = kSwidth2/2.;
366 par_trd[2] = kSlenTR2/2.;
367 par_trd[3] = kSheight/2.;
368 gMC->Gsvolu("TRD2","TRD1",idtmed[1302-1],par_trd,npar_trd);
369
370 par_trd[0] = kSwidth1/2.;
371 par_trd[1] = kSwidth2/2.;
372 par_trd[2] = kSlenTR3/2.;
373 par_trd[3] = kSheight/2.;
374 gMC->Gsvolu("TRD3","TRD1",idtmed[1302-1],par_trd,npar_trd);
375
376 }
82bbf98a 377
378 // The aluminum frames - readout + electronics (Al)
379 // The inner chambers
380 gMC->Gsvolu("UAFI","BOX ",idtmed[1301-1],par_dum,0);
381 // The middle chambers
382 gMC->Gsvolu("UAFM","BOX ",idtmed[1301-1],par_dum,0);
383 // The outer chambers
384 gMC->Gsvolu("UAFO","BOX ",idtmed[1301-1],par_dum,0);
385
386 // The inner part of the aluminum frames (Air)
387 // The inner chambers
388 gMC->Gsvolu("UAII","BOX ",idtmed[1302-1],par_dum,0);
389 // The middle chambers
390 gMC->Gsvolu("UAIM","BOX ",idtmed[1302-1],par_dum,0);
391 // The outer chambers
392 gMC->Gsvolu("UAIO","BOX ",idtmed[1302-1],par_dum,0);
393
394 // The carbon frames - radiator + driftchamber (C)
395 // The inner chambers
396 gMC->Gsvolu("UCFI","BOX ",idtmed[1307-1],par_dum,0);
397 // The middle chambers
398 gMC->Gsvolu("UCFM","BOX ",idtmed[1307-1],par_dum,0);
399 // The outer chambers
400 gMC->Gsvolu("UCFO","BOX ",idtmed[1307-1],par_dum,0);
401
402 // The inner part of the carbon frames (Air)
403 // The inner chambers
404 gMC->Gsvolu("UCII","BOX ",idtmed[1302-1],par_dum,0);
405 // The middle chambers
406 gMC->Gsvolu("UCIM","BOX ",idtmed[1302-1],par_dum,0);
407 // The outer chambers
408 gMC->Gsvolu("UCIO","BOX ",idtmed[1302-1],par_dum,0);
409
410 // The material layers inside the chambers
411 par_cha[0] = -1.;
412 par_cha[1] = -1.;
413 // G10 layer (radiator seal)
414 par_cha[2] = kSeThick/2;
415 gMC->Gsvolu("UL01","BOX ",idtmed[1313-1],par_cha,npar_cha);
416 // CO2 layer (radiator)
417 par_cha[2] = kRaThick/2;
418 gMC->Gsvolu("UL02","BOX ",idtmed[1312-1],par_cha,npar_cha);
419 // PE layer (radiator)
420 par_cha[2] = kPeThick/2;
421 gMC->Gsvolu("UL03","BOX ",idtmed[1303-1],par_cha,npar_cha);
422 // Mylar layer (entrance window + HV cathode)
423 par_cha[2] = kMyThick/2;
424 gMC->Gsvolu("UL04","BOX ",idtmed[1308-1],par_cha,npar_cha);
425 // Xe/Isobutane layer (drift volume, sensitive)
426 par_cha[2] = kDrThick/2.;
427 gMC->Gsvolu("UL05","BOX ",idtmed[1309-1],par_cha,npar_cha);
428 // Xe/Isobutane layer (amplification volume, not sensitive)
429 par_cha[2] = kAmThick/2.;
430 gMC->Gsvolu("UL06","BOX ",idtmed[1309-1],par_cha,npar_cha);
431
432 // Cu layer (pad plane)
433 par_cha[2] = kCuThick/2;
434 gMC->Gsvolu("UL07","BOX ",idtmed[1305-1],par_cha,npar_cha);
435 // G10 layer (support structure)
436 par_cha[2] = kSuThick/2;
437 gMC->Gsvolu("UL08","BOX ",idtmed[1313-1],par_cha,npar_cha);
438 // Cu layer (FEE + signal lines)
439 par_cha[2] = kFeThick/2;
440 gMC->Gsvolu("UL09","BOX ",idtmed[1305-1],par_cha,npar_cha);
441 // PE layer (cooling devices)
442 par_cha[2] = kCoThick/2;
443 gMC->Gsvolu("UL10","BOX ",idtmed[1303-1],par_cha,npar_cha);
444 // Water layer (cooling)
445 par_cha[2] = kWaThick/2;
446 gMC->Gsvolu("UL11","BOX ",idtmed[1314-1],par_cha,npar_cha);
447
448 // Position the layers in the chambers
449 xpos = 0;
450 ypos = 0;
451
452 // G10 layer (radiator seal)
453 zpos = kSeZpos;
454 gMC->Gspos("UL01",1,"UCII",xpos,ypos,zpos,0,"ONLY");
455 gMC->Gspos("UL01",2,"UCIM",xpos,ypos,zpos,0,"ONLY");
456 gMC->Gspos("UL01",3,"UCIO",xpos,ypos,zpos,0,"ONLY");
457 // CO2 layer (radiator)
458 zpos = kRaZpos;
459 gMC->Gspos("UL02",1,"UCII",xpos,ypos,zpos,0,"ONLY");
460 gMC->Gspos("UL02",2,"UCIM",xpos,ypos,zpos,0,"ONLY");
461 gMC->Gspos("UL02",3,"UCIO",xpos,ypos,zpos,0,"ONLY");
462 // PE layer (radiator)
463 zpos = 0;
464 gMC->Gspos("UL03",1,"UL02",xpos,ypos,zpos,0,"ONLY");
465 // Mylar layer (entrance window + HV cathode)
466 zpos = kMyZpos;
467 gMC->Gspos("UL04",1,"UCII",xpos,ypos,zpos,0,"ONLY");
468 gMC->Gspos("UL04",2,"UCIM",xpos,ypos,zpos,0,"ONLY");
469 gMC->Gspos("UL04",3,"UCIO",xpos,ypos,zpos,0,"ONLY");
470 // Xe/Isobutane layer (drift volume)
471 zpos = kDrZpos;
472 gMC->Gspos("UL05",1,"UCII",xpos,ypos,zpos,0,"ONLY");
473 gMC->Gspos("UL05",2,"UCIM",xpos,ypos,zpos,0,"ONLY");
474 gMC->Gspos("UL05",3,"UCIO",xpos,ypos,zpos,0,"ONLY");
475 // Xe/Isobutane layer (amplification volume)
476 zpos = kAmZpos;
477 gMC->Gspos("UL06",1,"UCII",xpos,ypos,zpos,0,"ONLY");
478 gMC->Gspos("UL06",2,"UCIM",xpos,ypos,zpos,0,"ONLY");
479 gMC->Gspos("UL06",3,"UCIO",xpos,ypos,zpos,0,"ONLY");
480
481 // Cu layer (pad plane)
482 zpos = kCuZpos;
483 gMC->Gspos("UL07",1,"UAII",xpos,ypos,zpos,0,"ONLY");
484 gMC->Gspos("UL07",2,"UAIM",xpos,ypos,zpos,0,"ONLY");
485 gMC->Gspos("UL07",3,"UAIO",xpos,ypos,zpos,0,"ONLY");
486 // G10 layer (support structure)
487 zpos = kSuZpos;
488 gMC->Gspos("UL08",1,"UAII",xpos,ypos,zpos,0,"ONLY");
489 gMC->Gspos("UL08",2,"UAIM",xpos,ypos,zpos,0,"ONLY");
490 gMC->Gspos("UL08",3,"UAIO",xpos,ypos,zpos,0,"ONLY");
491 // Cu layer (FEE + signal lines)
492 zpos = kFeZpos;
493 gMC->Gspos("UL09",1,"UAII",xpos,ypos,zpos,0,"ONLY");
494 gMC->Gspos("UL09",2,"UAIM",xpos,ypos,zpos,0,"ONLY");
495 gMC->Gspos("UL09",3,"UAIO",xpos,ypos,zpos,0,"ONLY");
496 // PE layer (cooling devices)
497 zpos = kCoZpos;
498 gMC->Gspos("UL10",1,"UAII",xpos,ypos,zpos,0,"ONLY");
499 gMC->Gspos("UL10",2,"UAIM",xpos,ypos,zpos,0,"ONLY");
500 gMC->Gspos("UL10",3,"UAIO",xpos,ypos,zpos,0,"ONLY");
501 // Water layer (cooling)
502 zpos = kWaZpos;
503 gMC->Gspos("UL11",1,"UAII",xpos,ypos,zpos,0,"ONLY");
504 gMC->Gspos("UL11",1,"UAIM",xpos,ypos,zpos,0,"ONLY");
505 gMC->Gspos("UL11",1,"UAIO",xpos,ypos,zpos,0,"ONLY");
506
507 // Position the chambers in the TRD mother volume
8459a454 508 for (iplan = 1; iplan <= kNplan; iplan++) {
82bbf98a 509
510 // The inner chambers ---------------------------------------------------------------
511
512 // the aluminum frame
82bbf98a 513 par_cha[0] = fCwidth[iplan-1]/2.;
514 par_cha[1] = fClengthI[iplan-1]/2.;
515 par_cha[2] = kCaframe/2.;
516 xpos = 0.;
517 ypos = 0.;
518 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 519 gMC->Gsposp("UAFI",iplan ,"TRD1",xpos,ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 520
521 // the inner part of the aluminum frame
82bbf98a 522 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
523 par_cha[1] = fClengthI[iplan-1]/2. - kCathick;
524 par_cha[2] = kCaframe/2.;
525 xpos = 0.;
526 ypos = 0.;
527 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 528 gMC->Gsposp("UAII",iplan ,"TRD1",xpos,ypos,zpos,0,"ONLY",par_cha,npar_cha);
82bbf98a 529
530 // the carbon frame
82bbf98a 531 par_cha[0] = fCwidth[iplan-1]/2.;
532 par_cha[1] = fClengthI[iplan-1]/2.;
533 par_cha[2] = kCcframe/2.;
534 xpos = 0.;
535 ypos = 0.;
536 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 537 gMC->Gsposp("UCFI",iplan ,"TRD1",xpos,ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 538
539 // the inner part of the carbon frame
82bbf98a 540 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
541 par_cha[1] = fClengthI[iplan-1]/2. - kCcthick;
542 par_cha[2] = kCcframe/2.;
543 xpos = 0.;
544 ypos = 0.;
545 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 546 gMC->Gsposp("UCII",iplan ,"TRD1",xpos,ypos,zpos,0,"ONLY",par_cha,npar_cha);
82bbf98a 547
548 // The middle chambers --------------------------------------------------------------
549
550 // the aluminum frame
82bbf98a 551 par_cha[0] = fCwidth[iplan-1]/2.;
5c7f4665 552 par_cha[1] = fClengthM1[iplan-1]/2.;
82bbf98a 553 par_cha[2] = kCaframe/2.;
554 xpos = 0.;
5c7f4665 555 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1]/2.;
82bbf98a 556 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 557 gMC->Gsposp("UAFM",iplan ,"TRD1",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
558 gMC->Gsposp("UAFM",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 559
560 // the inner part of the aluminum frame
5c7f4665 561 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
562 par_cha[1] = fClengthM1[iplan-1]/2. - kCathick;
82bbf98a 563 par_cha[2] = kCaframe/2.;
564 xpos = 0.;
5c7f4665 565 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1]/2.;
82bbf98a 566 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 567 gMC->Gsposp("UAIM",iplan ,"TRD1",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
568 gMC->Gsposp("UAIM",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"ONLY",par_cha,npar_cha);
82bbf98a 569
570 // the carbon frame
82bbf98a 571 par_cha[0] = fCwidth[iplan-1]/2.;
5c7f4665 572 par_cha[1] = fClengthM1[iplan-1]/2.;
82bbf98a 573 par_cha[2] = kCcframe/2.;
574 xpos = 0.;
5c7f4665 575 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1]/2.;
576 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
577 gMC->Gsposp("UCFM",iplan ,"TRD1",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
578 gMC->Gsposp("UCFM",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 579
580 // the inner part of the carbon frame
5c7f4665 581 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
582 par_cha[1] = fClengthM1[iplan-1]/2. - kCcthick;
82bbf98a 583 par_cha[2] = kCcframe/2.;
584 xpos = 0.;
5c7f4665 585 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1]/2.;
586 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
587 gMC->Gsposp("UCIM",iplan ,"TRD1",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
588 gMC->Gsposp("UCIM",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"ONLY",par_cha,npar_cha);
589
590 // Only for the geometry with holes
591 if (fHole) {
592
593 // the aluminum frame
594 par_cha[0] = fCwidth[iplan-1]/2.;
595 par_cha[1] = fClengthM2[iplan-1]/2.;
596 par_cha[2] = kCaframe/2.;
597 xpos = 0.;
598 ypos = fClengthM2[iplan-1]/2. - kSlenTR2/2.;
599 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
600 gMC->Gsposp("UAFM",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
601
602 // the inner part of the aluminum frame
603 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
604 par_cha[1] = fClengthM2[iplan-1]/2. - kCathick;
605 par_cha[2] = kCaframe/2.;
606 xpos = 0.;
607 ypos = fClengthM2[iplan-1]/2. - kSlenTR2/2.;
608 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
609 gMC->Gsposp("UAIM",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
610
611 // the carbon frame
612 par_cha[0] = fCwidth[iplan-1]/2.;
613 par_cha[1] = fClengthM2[iplan-1]/2.;
614 par_cha[2] = kCcframe/2.;
615 xpos = 0.;
616 ypos = fClengthM2[iplan-1]/2. - kSlenTR2/2.;
617 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
618 gMC->Gsposp("UCFM",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
619
620 // the inner part of the carbon frame
621 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
622 par_cha[1] = fClengthM2[iplan-1]/2. - kCcthick;
623 par_cha[2] = kCcframe/2.;
624 xpos = 0.;
625 ypos = fClengthM2[iplan-1]/2. - kSlenTR2/2.;
626 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
627 gMC->Gsposp("UCIM",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
628
629 }
82bbf98a 630
631 // The outer chambers ---------------------------------------------------------------
632
633 // the aluminum frame
82bbf98a 634 par_cha[0] = fCwidth[iplan-1]/2.;
5c7f4665 635 par_cha[1] = fClengthO1[iplan-1]/2.;
82bbf98a 636 par_cha[2] = kCaframe/2.;
637 xpos = 0.;
5c7f4665 638 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1] + fClengthO1[iplan-1]/2.;
82bbf98a 639 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 640 gMC->Gsposp("UAFO",iplan ,"TRD1",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
641 gMC->Gsposp("UAFO",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 642
643 // the inner part of the aluminum frame
5c7f4665 644 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
645 par_cha[1] = fClengthO1[iplan-1]/2. - kCathick;
82bbf98a 646 par_cha[2] = kCaframe/2.;
647 xpos = 0.;
5c7f4665 648 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1] + fClengthO1[iplan-1]/2.;
82bbf98a 649 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
5c7f4665 650 gMC->Gsposp("UAIO",iplan ,"TRD1",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
651 gMC->Gsposp("UAIO",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"ONLY",par_cha,npar_cha);
82bbf98a 652
653 // the carbon frame
82bbf98a 654 par_cha[0] = fCwidth[iplan-1]/2.;
5c7f4665 655 par_cha[1] = fClengthO1[iplan-1]/2.;
82bbf98a 656 par_cha[2] = kCcframe/2.;
657 xpos = 0.;
5c7f4665 658 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1] + fClengthO1[iplan-1]/2.;
659 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
660 gMC->Gsposp("UCFO",iplan, "TRD1",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
661 gMC->Gsposp("UCFO",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"MANY",par_cha,npar_cha);
82bbf98a 662
663 // the inner part of the carbon frame
5c7f4665 664 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
665 par_cha[1] = fClengthO1[iplan-1]/2. - kCcthick;
82bbf98a 666 par_cha[2] = kCcframe/2.;
667 xpos = 0.;
5c7f4665 668 ypos = fClengthI[iplan-1]/2. + fClengthM1[iplan-1] + fClengthO1[iplan-1]/2.;
669 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
670 gMC->Gsposp("UCIO",iplan ,"TRD1",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
671 gMC->Gsposp("UCIO",iplan+ kNplan,"TRD1",xpos,-ypos,zpos,0,"ONLY",par_cha,npar_cha);
672
673 // Only for the geometry with holes
674 if (fHole) {
675
676 // the aluminum frame
677 par_cha[0] = fCwidth[iplan-1]/2.;
678 par_cha[1] = fClengthO2[iplan-1]/2.;
679 par_cha[2] = kCaframe/2.;
680 xpos = 0.;
681 ypos = fClengthM2[iplan-1] + fClengthO2[iplan-1]/2. - kSlenTR2/2.;
682 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
683 gMC->Gsposp("UAFO",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
684
685 // the inner part of the aluminum frame
686 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
687 par_cha[1] = fClengthO2[iplan-1]/2. - kCathick;
688 par_cha[2] = kCaframe/2.;
689 xpos = 0.;
690 ypos = fClengthM2[iplan-1] + fClengthO2[iplan-1]/2. - kSlenTR2/2.;
691 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
692 gMC->Gsposp("UAIO",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
693
694 // the carbon frame
695 par_cha[0] = fCwidth[iplan-1]/2.;
696 par_cha[1] = fClengthO2[iplan-1]/2.;
697 par_cha[2] = kCcframe/2.;
698 xpos = 0.;
699 ypos = fClengthM2[iplan-1] + fClengthO2[iplan-1]/2. - kSlenTR2/2.;
700 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
701 gMC->Gsposp("UCFO",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
702
703 // the inner part of the carbon frame
704 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
705 par_cha[1] = fClengthO2[iplan-1]/2. - kCcthick;
706 par_cha[2] = kCcframe/2.;
707 xpos = 0.;
708 ypos = fClengthM2[iplan-1] + fClengthO2[iplan-1]/2. - kSlenTR2/2.;
709 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
710 gMC->Gsposp("UCIO",iplan+2*kNplan,"TRD2",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
711
712 // the aluminum frame
713 par_cha[0] = fCwidth[iplan-1]/2.;
714 par_cha[1] = fClengthO3[iplan-1]/2.;
715 par_cha[2] = kCaframe/2.;
716 xpos = 0.;
717 ypos = fClengthO3[iplan-1]/2. - kSlenTR3/2.;
718 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
719 gMC->Gsposp("UAFO",iplan+4*kNplan,"TRD3",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
720
721 // the inner part of the aluminum frame
722 par_cha[0] = fCwidth[iplan-1]/2. - kCathick;
723 par_cha[1] = fClengthO3[iplan-1]/2. - kCathick;
724 par_cha[2] = kCaframe/2.;
725 xpos = 0.;
726 ypos = fClengthO3[iplan-1]/2. - kSlenTR3/2.;
727 zpos = kCheight - kCaframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
728 gMC->Gsposp("UAIO",iplan+4*kNplan,"TRD3",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
729
730 // the carbon frame
731 par_cha[0] = fCwidth[iplan-1]/2.;
732 par_cha[1] = fClengthO3[iplan-1]/2.;
733 par_cha[2] = kCcframe/2.;
734 xpos = 0.;
735 ypos = fClengthO3[iplan-1]/2. - kSlenTR3/2.;
736 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
737 gMC->Gsposp("UCFO",iplan+4*kNplan,"TRD3",xpos, ypos,zpos,0,"MANY",par_cha,npar_cha);
738
739 // the inner part of the carbon frame
740 par_cha[0] = fCwidth[iplan-1]/2. - kCcthick;
741 par_cha[1] = fClengthO3[iplan-1]/2. - kCcthick;
742 par_cha[2] = kCcframe/2.;
743 xpos = 0.;
744 ypos = fClengthO3[iplan-1]/2. - kSlenTR3/2.;
745 zpos = kCcframe/2. - kSheight/2. + (iplan-1) * (kCheight + kCspace);
746 gMC->Gsposp("UCIO",iplan+4*kNplan,"TRD3",xpos, ypos,zpos,0,"ONLY",par_cha,npar_cha);
747
748 }
82bbf98a 749
750 }
d3f347ff 751
5c7f4665 752 if (fHole) {
753 xpos = 0.;
754 ypos = 0.;
755 zpos = 0.;
756 gMC->Gspos("TRD1",1,"BTR1",xpos,ypos,zpos,0,"ONLY");
757 gMC->Gspos("TRD2",1,"BTR2",xpos,ypos,zpos,0,"ONLY");
758 gMC->Gspos("TRD3",1,"BTR3",xpos,ypos,zpos,0,"ONLY");
759 }
760 else {
761 xpos = 0.;
762 ypos = 0.;
763 zpos = 0.;
764 gMC->Gspos("TRD1",1,"BTR1",xpos,ypos,zpos,0,"ONLY");
765 gMC->Gspos("TRD1",2,"BTR2",xpos,ypos,zpos,0,"ONLY");
766 gMC->Gspos("TRD1",3,"BTR3",xpos,ypos,zpos,0,"ONLY");
767 }
768
82bbf98a 769}
770
771//_____________________________________________________________________________
772void AliTRD::CreateMaterials()
773{
fe4da5cc 774 //
775 // Create the materials for the TRD
776 // Origin Y.Foka
777 //
778
fe4da5cc 779 Int_t ISXFLD = gAlice->Field()->Integ();
780 Float_t SXMGMX = gAlice->Field()->Max();
781
d3f347ff 782 // For polyethilene (CH2)
783 Float_t ape[2] = { 12., 1. };
784 Float_t zpe[2] = { 6., 1. };
785 Float_t wpe[2] = { 1., 2. };
786 Float_t dpe = 0.95;
787
788 // For mylar (C5H4O2)
789 Float_t amy[3] = { 12., 1., 16. };
790 Float_t zmy[3] = { 6., 1., 8. };
791 Float_t wmy[3] = { 5., 4., 2. };
fe4da5cc 792 Float_t dmy = 1.39;
d3f347ff 793
794 // For CO2
795 Float_t aco[2] = { 12., 16. };
796 Float_t zco[2] = { 6., 8. };
797 Float_t wco[2] = { 1., 2. };
798 Float_t dco = 0.001977;
799
800 // For water
801 Float_t awa[2] = { 1., 16. };
802 Float_t zwa[2] = { 1., 8. };
803 Float_t wwa[2] = { 2., 1. };
804 Float_t dwa = 1.0;
805
806 // For isobutane (C4H10)
807 Float_t ais[2] = { 12., 1. };
808 Float_t zis[2] = { 6., 1. };
809 Float_t wis[2] = { 4., 10. };
810 Float_t dis = 0.00267;
811
812 // For Xe/CO2-gas-mixture
813 // Xe-content of the Xe/CO2-mixture (90% / 10%)
814 Float_t fxc = .90;
815 // Xe-content of the Xe/Isobutane-mixture (97% / 3%)
816 Float_t fxi = .97;
fe4da5cc 817 Float_t dxe = .005858;
818
d3f347ff 819 // General tracking parameter
fe4da5cc 820 Float_t tmaxfd = -10.;
821 Float_t stemax = -1e10;
d3f347ff 822 Float_t deemax = -0.1;
823 Float_t epsil = 1e-4;
824 Float_t stmin = -0.001;
fe4da5cc 825
826 Float_t absl, radl, d, buf[1];
827 Float_t agm[2], dgm, zgm[2], wgm[2];
d3f347ff 828 Int_t nbuf;
fe4da5cc 829
d3f347ff 830 //////////////////////////////////////////////////////////////////////////
fe4da5cc 831 // Define Materials
d3f347ff 832 //////////////////////////////////////////////////////////////////////////
833
834 AliMaterial( 1, "Al $", 26.98, 13.0, 2.7 , 8.9 , 37.2);
835 AliMaterial( 2, "Air$", 14.61, 7.3, 0.001205, 30420.0 , 67500.0);
836 AliMaterial( 4, "Xe $", 131.29, 54.0, dxe , 1447.59, 0.0);
837 AliMaterial( 5, "Cu $", 63.54, 29.0, 8.96 , 1.43, 14.8);
838 AliMaterial( 6, "C $", 12.01, 6.0, 2.265 , 18.8 , 74.4);
839 AliMaterial(12, "G10$", 20.00, 10.0, 1.7 , 19.4 , 999.0);
840
841 // Mixtures
842 AliMixture(3, "Polyethilene$", ape, zpe, dpe, -2, wpe);
843 AliMixture(7, "Mylar$", amy, zmy, dmy, -3, wmy);
844 AliMixture(8, "CO2$", aco, zco, dco, -2, wco);
845 AliMixture(9, "Isobutane$", ais, zis, dis, -2, wis);
82bbf98a 846 AliMixture(13,"Water$", awa, zwa, dwa, -2, wwa);
d3f347ff 847
848 // Gas mixtures
82bbf98a 849 Char_t namate[21];
d3f347ff 850 // Xe/CO2-mixture
851 // Get properties of Xe
cfce8870 852 gMC->Gfmate((*fIdmate)[4], namate, agm[0], zgm[0], d, radl, absl, buf, nbuf);
d3f347ff 853 // Get properties of CO2
cfce8870 854 gMC->Gfmate((*fIdmate)[8], namate, agm[1], zgm[1], d, radl, absl, buf, nbuf);
d3f347ff 855 // Create gas mixture
856 wgm[0] = fxc;
857 wgm[1] = 1. - fxc;
fe4da5cc 858 dgm = wgm[0] * dxe + wgm[1] * dco;
d3f347ff 859 AliMixture(10, "Gas mixture 1$", agm, zgm, dgm, 2, wgm);
860 // Xe/Isobutane-mixture
861 // Get properties of Xe
cfce8870 862 gMC->Gfmate((*fIdmate)[4], namate, agm[0], zgm[0], d, radl, absl, buf, nbuf);
d3f347ff 863 // Get properties of Isobutane
cfce8870 864 gMC->Gfmate((*fIdmate)[9], namate, agm[1], zgm[1], d, radl, absl, buf, nbuf);
d3f347ff 865 // Create gas mixture
866 wgm[0] = fxi;
867 wgm[1] = 1. - fxi;
868 dgm = wgm[0] * dxe + wgm[1] * dis;
869 AliMixture(11, "Gas mixture 2$", agm, zgm, dgm, 2, wgm);
870
871 //////////////////////////////////////////////////////////////////////////
fe4da5cc 872 // Tracking Media Parameters
d3f347ff 873 //////////////////////////////////////////////////////////////////////////
874
875 // Al Frame
ad51aeb0 876 AliMedium(1, "Al Frame$", 1, 0, ISXFLD, SXMGMX
d3f347ff 877 , tmaxfd, stemax, deemax, epsil, stmin);
878 // Air
ad51aeb0 879 AliMedium(2, "Air$", 2, 0, ISXFLD, SXMGMX
d3f347ff 880 , tmaxfd, stemax, deemax, epsil, stmin);
881 // Polyethilene
ad51aeb0 882 AliMedium(3, "Radiator$", 3, 0, ISXFLD, SXMGMX
d3f347ff 883 , tmaxfd, stemax, deemax, epsil, stmin);
884 // Xe
ad51aeb0 885 AliMedium(4, "Xe$", 4, 1, ISXFLD, SXMGMX
d3f347ff 886 , tmaxfd, stemax, deemax, epsil, stmin);
887 // Cu pads
ad51aeb0 888 AliMedium(5, "Padplane$", 5, 1, ISXFLD, SXMGMX
d3f347ff 889 , tmaxfd, stemax, deemax, epsil, stmin);
890 // Fee + cables
ad51aeb0 891 AliMedium(6, "Readout$", 1, 0, ISXFLD, SXMGMX
d3f347ff 892 , tmaxfd, stemax, deemax, epsil, stmin);
893 // C frame
ad51aeb0 894 AliMedium(7, "C Frame$", 6, 0, ISXFLD, SXMGMX
d3f347ff 895 , tmaxfd, stemax, deemax, epsil, stmin);
896 // Mylar foils
ad51aeb0 897 AliMedium(8, "Mylar$", 7, 0, ISXFLD, SXMGMX
d3f347ff 898 , tmaxfd, stemax, deemax, epsil, stmin);
899 if (fGasMix == 1) {
900 // Gas-mixture (Xe/CO2)
ad51aeb0 901 AliMedium(9, "Gas-mix$", 10, 1, ISXFLD, SXMGMX
d3f347ff 902 , tmaxfd, stemax, deemax, epsil, stmin);
903 }
904 else {
905 // Gas-mixture (Xe/Isobutane)
ad51aeb0 906 AliMedium(9, "Gas-mix$", 11, 1, ISXFLD, SXMGMX
d3f347ff 907 , tmaxfd, stemax, deemax, epsil, stmin);
908 }
909 // Nomex-honeycomb (use carbon for the time being)
ad51aeb0 910 AliMedium(10, "Nomex$", 6, 0, ISXFLD, SXMGMX
d3f347ff 911 , tmaxfd, stemax, deemax, epsil, stmin);
912 // Kapton foils (use Mylar for the time being)
ad51aeb0 913 AliMedium(11, "Kapton$", 7, 0, ISXFLD, SXMGMX
d3f347ff 914 , tmaxfd, stemax, deemax, epsil, stmin);
915 // Gas-filling of the radiator
ad51aeb0 916 AliMedium(12, "CO2$", 8, 0, ISXFLD, SXMGMX
d3f347ff 917 , tmaxfd, stemax, deemax, epsil, stmin);
918 // G10-plates
ad51aeb0 919 AliMedium(13, "G10-plates$",12, 0, ISXFLD, SXMGMX
d3f347ff 920 , tmaxfd, stemax, deemax, epsil, stmin);
921 // Cooling water
ad51aeb0 922 AliMedium(14, "Water$", 13, 0, ISXFLD, SXMGMX
d3f347ff 923 , tmaxfd, stemax, deemax, epsil, stmin);
924
fe4da5cc 925}
926
927//_____________________________________________________________________________
82bbf98a 928void AliTRD::DrawModule()
929{
930 //
931 // Draw a shaded view of the Transition Radiation Detector version 0
932 //
933
934 // Set everything unseen
935 gMC->Gsatt("*" ,"SEEN",-1);
936
937 // Set ALIC mother transparent
938 gMC->Gsatt("ALIC","SEEN", 0);
939
940 // Set the volumes visible
5c7f4665 941 if (fHole) {
942 gMC->Gsatt("B071","SEEN", 0);
943 gMC->Gsatt("B074","SEEN", 0);
944 gMC->Gsatt("B075","SEEN", 0);
945 gMC->Gsatt("B077","SEEN", 0);
946 gMC->Gsatt("BTR1","SEEN", 0);
947 gMC->Gsatt("BTR2","SEEN", 0);
948 gMC->Gsatt("BTR3","SEEN", 0);
949 gMC->Gsatt("TRD1","SEEN", 0);
950 gMC->Gsatt("TRD2","SEEN", 0);
951 gMC->Gsatt("TRD3","SEEN", 0);
952 }
953 else {
954 gMC->Gsatt("B071","SEEN", 0);
955 gMC->Gsatt("B074","SEEN", 0);
956 gMC->Gsatt("B075","SEEN", 0);
957 gMC->Gsatt("B077","SEEN", 0);
958 gMC->Gsatt("BTR1","SEEN", 0);
959 gMC->Gsatt("BTR2","SEEN", 0);
960 gMC->Gsatt("BTR3","SEEN", 0);
961 gMC->Gsatt("TRD1","SEEN", 0);
962 }
82bbf98a 963 gMC->Gsatt("UCII","SEEN", 0);
964 gMC->Gsatt("UCIM","SEEN", 0);
965 gMC->Gsatt("UCIO","SEEN", 0);
966 gMC->Gsatt("UL02","SEEN", 1);
967 gMC->Gsatt("UL05","SEEN", 1);
968 gMC->Gsatt("UL06","SEEN", 1);
969
970 gMC->Gdopt("hide", "on");
971 gMC->Gdopt("shad", "on");
972 gMC->Gsatt("*", "fill", 7);
973 gMC->SetClipBox(".");
974 gMC->SetClipBox("*", 0, 2000, -2000, 2000, -2000, 2000);
975 gMC->DefaultRange();
976 gMC->Gdraw("alic", 40, 30, 0, 12, 9.4, .021, .021);
977 gMC->Gdhead(1111, "Transition Radiation Detector");
978 gMC->Gdman(18, 4, "MAN");
979
980}
981
982//_____________________________________________________________________________
fe4da5cc 983Int_t AliTRD::DistancetoPrimitive(Int_t , Int_t )
984{
985 //
986 // Distance between the mouse and the TRD detector on the screen
987 // Dummy routine
82bbf98a 988
989 return 9999;
990
fe4da5cc 991}
992
993//_____________________________________________________________________________
994void AliTRD::Init()
995{
996 //
997 // Initialise the TRD detector after the geometry has been created
998 //
82bbf98a 999
5c7f4665 1000 Int_t i;
8459a454 1001 Int_t iplan;
5c7f4665 1002
1003 printf("\n");
1004 for(i=0;i<35;i++) printf("*");
1005 printf(" TRD_INIT ");
1006 for(i=0;i<35;i++) printf("*");
1007 printf("\n");
1008
fe4da5cc 1009 // Here the TRD initialisation code (if any!)
d3f347ff 1010 if (fGasMix == 1)
1011 printf(" Gas Mixture: 90%% Xe + 10%% CO2\n");
1012 else
1013 printf(" Gas Mixture: 97%% Xe + 3%% Isobutane\n");
82bbf98a 1014
5c7f4665 1015 if (fHole)
1016 printf(" Geometry with holes\n");
1017 else
1018 printf(" Full geometry\n");
1019
1020 // The default pad dimensions
1021 if (!(fRowPadSize)) fRowPadSize = 4.5;
1022 if (!(fColPadSize)) fColPadSize = 1.0;
1023 if (!(fTimeBinSize)) fTimeBinSize = 0.1;
1024
1025 // The maximum number of pads
1026 // and the position of pad 0,0,0
1027 //
1028 // chambers seen from the top:
1029 // +----------------------------+
1030 // | |
1031 // | | ^
1032 // | | rphi|
1033 // | | |
1034 // |0 | |
1035 // +----------------------------+ +------>
1036 // z
1037 // chambers seen from the side: ^
1038 // +----------------------------+ time|
1039 // | | |
1040 // |0 | |
1041 // +----------------------------+ +------>
1042 // z
1043 //
8459a454 1044 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 1045
1046 // The pad row (z-direction)
1047 for (Int_t isect = 0; isect < kNsect; isect++) {
1048 Float_t clengthI = fClengthI[iplan];
1049 Float_t clengthM = fClengthM1[iplan];
1050 Float_t clengthO = fClengthO1[iplan];
1051 if (fHole) {
1052 switch (isect) {
1053 case 12:
1054 case 13:
1055 case 14:
1056 case 15:
1057 case 16:
1058 clengthM = fClengthM2[iplan];
1059 clengthO = fClengthO2[iplan];
1060 break;
1061 case 4:
1062 case 5:
1063 case 6:
1064 clengthO = fClengthO3[iplan];
1065 break;
1066 };
1067 }
1068 fRowMax[iplan][0][isect] = 1 + TMath::Nint((clengthO - 2. * kCcthick)
1069 / fRowPadSize - 0.5);
1070 fRowMax[iplan][1][isect] = 1 + TMath::Nint((clengthM - 2. * kCcthick)
1071 / fRowPadSize - 0.5);
1072 fRowMax[iplan][2][isect] = 1 + TMath::Nint((clengthI - 2. * kCcthick)
1073 / fRowPadSize - 0.5);
1074 fRowMax[iplan][3][isect] = 1 + TMath::Nint((clengthM - 2. * kCcthick)
1075 / fRowPadSize - 0.5);
1076 fRowMax[iplan][4][isect] = 1 + TMath::Nint((clengthO - 2. * kCcthick)
1077 / fRowPadSize - 0.5);
1078 fRow0[iplan][0][isect] = -clengthI/2. - clengthM - clengthO + kCcthick;
1079 fRow0[iplan][1][isect] = -clengthI/2. - clengthM + kCcthick;
1080 fRow0[iplan][2][isect] = -clengthI/2. + kCcthick;
1081 fRow0[iplan][3][isect] = clengthI/2. + kCcthick;
1082 fRow0[iplan][4][isect] = clengthI/2. + clengthM + kCcthick;
1083 }
1084
1085 // The pad column (rphi-direction)
1086 fColMax[iplan] = 1 + TMath::Nint((fCwidth[iplan] - 2. * kCcthick)
1087 / fColPadSize - 0.5);
1088 fCol0[iplan] = -fCwidth[iplan]/2. + kCcthick;
1089
1090 }
1091
1092 // The time bucket
1093 fTimeMax = 1 + TMath::Nint(kDrThick / fTimeBinSize - 0.5);
94c641ff 1094 for (iplan = 0; iplan < kNplan; iplan++) {
5c7f4665 1095 fTime0[iplan] = kRmin + kCcframe/2. + kDrZpos - 0.5 * kDrThick
1096 + iplan * (kCheight + kCspace);
1097 }
1098
1099}
1100
1101//_____________________________________________________________________________
1102void AliTRD::MakeBranch(Option_t* option)
1103{
1104 //
1105 // Create Tree branches for the TRD digits and cluster.
1106 //
1107
1108 Int_t buffersize = 4000;
1109 Char_t branchname[15];
1110
1111 AliDetector::MakeBranch(option);
1112
1113 Char_t *D = strstr(option,"D");
1114 sprintf(branchname,"%s",GetName());
1115 if (fDigits && gAlice->TreeD() && D) {
1116 gAlice->TreeD()->Branch(branchname,&fDigits, buffersize);
1117 printf("* AliTRD::MakeBranch * Making Branch %s for digits in TreeD\n",branchname);
1118 }
1119
1120 sprintf(branchname,"%scluster",GetName());
1121 if (fClusters && gAlice->TreeD() && D) {
1122 gAlice->TreeD()->Branch(branchname,&fClusters,buffersize);
1123 printf("* AliTRD::MakeBranch * Making Branch %s for cluster in TreeD\n",branchname);
1124 }
1125
1126}
1127
1128//_____________________________________________________________________________
1129void AliTRD::SetTreeAddress()
1130{
1131 //
1132 // Set the branch addresses for the trees.
1133 //
1134
1135 Char_t branchname[15];
1136
1137 AliDetector::SetTreeAddress();
1138
1139 TBranch *branch;
1140 TTree *treeD = gAlice->TreeD();
1141
1142 if (treeD) {
1143 sprintf(branchname,"%scluster",GetName());
1144 if (fClusters) {
1145 branch = treeD->GetBranch(branchname);
1146 if (branch) branch->SetAddress(&fClusters);
1147 }
1148 }
1149
fe4da5cc 1150}
1151
d3f347ff 1152//_____________________________________________________________________________
b060c36f 1153void AliTRD::SetGasMix(Int_t imix)
d3f347ff 1154{
82bbf98a 1155 //
1156 // Defines the gas mixture (imix=0: Xe/Isobutane imix=1: Xe/CO2)
1157 //
1158
d3f347ff 1159 if ((imix < 0) || (imix > 1)) {
1160 printf("Wrong input value: %d\n",imix);
1161 printf("Use standard setting\n");
1162 fGasMix = 0;
1163 return;
1164 }
1165
1166 fGasMix = imix;
1167
1168}
1169
5c7f4665 1170//______________________________________________________________________________
1171void AliTRD::Streamer(TBuffer &R__b)
1172{
1173 // Stream an object of class AliTRD.
1174
1175 if (R__b.IsReading()) {
1176 Version_t R__v = R__b.ReadVersion(); if (R__v) { }
1177 AliDetector::Streamer(R__b);
1178 R__b >> fGasMix;
1179 R__b.ReadStaticArray(fClengthI);
1180 R__b.ReadStaticArray(fClengthM1);
1181 R__b.ReadStaticArray(fClengthM2);
1182 R__b.ReadStaticArray(fClengthO1);
1183 R__b.ReadStaticArray(fClengthO2);
1184 R__b.ReadStaticArray(fClengthO3);
1185 R__b.ReadStaticArray(fCwidth);
1186 R__b.ReadStaticArray((int*)fRowMax);
1187 R__b.ReadStaticArray(fColMax);
1188 R__b >> fTimeMax;
1189 R__b.ReadStaticArray((float*)fRow0);
1190 R__b.ReadStaticArray(fCol0);
1191 R__b.ReadStaticArray(fTime0);
1192 R__b >> fRowPadSize;
1193 R__b >> fColPadSize;
1194 R__b >> fTimeBinSize;
1195 R__b >> fHole;
1196 // Stream the pointers but not the TClonesArray
1197 R__b >> fClusters; // diff
1198 //R__b >> fNclusters;
1199 } else {
1200 R__b.WriteVersion(AliTRD::IsA());
1201 AliDetector::Streamer(R__b);
1202 R__b << fGasMix;
1203 R__b.WriteArray(fClengthI, 6);
1204 R__b.WriteArray(fClengthM1, 6);
1205 R__b.WriteArray(fClengthM2, 6);
1206 R__b.WriteArray(fClengthO1, 6);
1207 R__b.WriteArray(fClengthO2, 6);
1208 R__b.WriteArray(fClengthO3, 6);
1209 R__b.WriteArray(fCwidth, 6);
1210 R__b.WriteArray((int*)fRowMax, 540);
1211 R__b.WriteArray(fColMax, 6);
1212 R__b << fTimeMax;
1213 R__b.WriteArray((float*)fRow0, 540);
1214 R__b.WriteArray(fCol0, 6);
1215 R__b.WriteArray(fTime0, 6);
1216 R__b << fRowPadSize;
1217 R__b << fColPadSize;
1218 R__b << fTimeBinSize;
1219 R__b << fHole;
1220 // Stream the pointers but not the TClonesArrays
1221 R__b << fClusters; // diff
1222 //R__b << fNclusters;
1223 }
1224
1225}
1226
fe4da5cc 1227ClassImp(AliTRDhit)
1228
1229//_____________________________________________________________________________
5c7f4665 1230AliTRDhit::AliTRDhit(Int_t shunt, Int_t track, Int_t *vol, Float_t *hits)
1231 :AliHit(shunt, track)
fe4da5cc 1232{
1233 //
1234 // Create a TRD hit
1235 //
1236
fe4da5cc 1237 // Store volume hierarchy
1238 fSector = vol[0];
1239 fChamber = vol[1];
1240 fPlane = vol[2];
82bbf98a 1241
fe4da5cc 1242 // Store position and charge
1243 fX = hits[0];
1244 fY = hits[1];
1245 fZ = hits[2];
1246 fQ = hits[3];
82bbf98a 1247
fe4da5cc 1248}
99d5402e 1249
1250ClassImp(AliTRDdigit)
1251
1252//_____________________________________________________________________________
1253AliTRDdigit::AliTRDdigit(Int_t *tracks, Int_t *digits)
1254 :AliDigit(tracks)
1255{
1256 //
1257 // Create a TRD digit
1258 //
1259
1260 // Store the volume hierarchy
1261 fSector = digits[0];
1262 fChamber = digits[1];
1263 fPlane = digits[2];
1264
1265 // Store the row, pad, and time bucket number
1266 fRow = digits[3];
1267 fCol = digits[4];
1268 fTime = digits[5];
1269
1270 // Store the signal amplitude
1271 fSignal = digits[6];
1272
1273}
5c7f4665 1274
1275ClassImp(AliTRDcluster)
1276
1277//_____________________________________________________________________________
1278AliTRDcluster::AliTRDcluster(Int_t *tracks, Int_t *cluster, Float_t* position)
1279 :TObject()
1280{
1281 //
1282 // Create a TRD cluster
1283 //
1284
1285 fSector = cluster[0];
1286 fChamber = cluster[1];
1287 fPlane = cluster[2];
1288
1289 fTimeSlice = cluster[3];
1290 fEnergy = cluster[4];
1291
1292 fX = position[0];
1293 fY = position[1];
1294 fZ = position[2];
1295
1296 fTracks[0] = tracks[0];
1297 fTracks[1] = tracks[1];
1298 fTracks[2] = tracks[2];
1299
1300}
1301