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Contents of /gpamela/gptrd/gptrdv.F

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Revision 3.2 - (show annotations) (download)
Tue Jun 21 02:42:34 2005 UTC (19 years, 5 months ago) by cafagna
Branch: MAIN
CVS Tags: v4r4, v4r5, v4r6, v4r7, v4r2, v4r3, v4r8, v4r9, v4r14, v4r12, v4r13, v4r10, v4r11, HEAD
Changes since 3.1: +317 -52 lines
Error occurred while calculating annotation data.
Major modification to the geometry and to the random number chain

1 *
2 * $Id: gptrdv.F,v 3.1.1.1 2002/07/11 16:02:01 cafagna Exp $
3 *
4 * $Log: gptrdv.F,v $
5 * Revision 3.1.1.1 2002/07/11 16:02:01 cafagna
6 * First GPAMELA release on CVS
7 *
8 *
9 *CMZ : 2.01/00 05/04/2000 14.35.18 by Marialuigia Ambriola
10 *CMZ : 2.00/00 03/03/2000 15.39.05 by Francesco Cafagna
11 *CMZ : 1.02/00 09/02/2000 13.11.57 by Francesco Cafagna
12 *CMZ : 1.00/02 15/03/96 16.04.21 by Francesco Cafagna
13 *-- Author : Francesco Cafagna 05/12/95
14 SUBROUTINE GPTRDV
15 ************************************************************************
16 * *
17 * Volume definition for TRD *
18 * Called by: GPGEO *
19 * Author: Francesco Cafagna, 05/12/95 17.25.32 *
20 * *
21 ************************************************************************
22 #include "gpgeo.inc"
23 #include "gpmed.inc"
24 *
25 INTEGER IROT,IVOLU,N,NMED,NUM,NAN
26 REAL X,Y,Z
27 *
28 * Define the TRDB volume
29 *
30 NMED=MN2
31 CALL GSVOLU('TRDB','BOX ',NMED,TRDB, 3,IVOLU)
32 *
33 * Define the TRAN volume
34 *
35 NMED=MAL
36 CALL GSVOLU('TRAN','BOX ',NMED,TRAN, 3,IVOLU)
37 *
38 * Define the TRAI volume
39 *
40 NMED=MN2
41 CALL GSVOLU('TRAI','BOX ',NMED,TRAI, 3,IVOLU)
42 *
43 * Define the TRBS volumes
44 *
45 NMED=MN2
46 CALL GSVOLU('TRBS','BOX ',NMED,TRBS, 3,IVOLU)
47 *ml: 10/11/66:
48 *
49 * Define the TRAL volumes
50 *
51 NMED=MAL
52 CALL GSVOLU('TRAL','BOX ',NMED,TRAL, 3,IVOLU)
53 *end ml.
54 *
55 * Define the TRSO volumes
56 *
57 NMED=MKAP
58 CALL GSVOLU('TRSO','TUBE',NMED,TRSO, 3,IVOLU)
59 *
60 * Define the TRSI volumes
61 *
62 NMED=MXE
63 CALL GSVOLU('TRSI','TUBE',NMED,TRSI, 3,IVOLU)
64 *
65 * Define the TRRA volumes
66 *
67 NMED=MTRAD
68 CALL GSVOLU('TRRA','BOX ',NMED,TRRA, 3,IVOLU)
69 c ml: 11/11/04:
70 *
71 * Define the TRR2 volumes
72 *
73 NMED=MTRAD
74 CALL GSVOLU('TRR2','BOX ',NMED,TRR2, 3,IVOLU)
75 *
76 * Define the TRR0 volumes
77 *
78 NMED=MCF
79 CALL GSVOLU('TRR0','BOX ',NMED,TRR0, 3,IVOLU)
80 *
81 * Define the TRI0 volumes
82 *
83 NMED=MN2
84 CALL GSVOLU('TRI0','BOX ',NMED,TRI0, 3,IVOLU)
85 *
86 * Define the TRRF volumes
87 *
88 NMED=MMAG
89 CALL GSVOLU('TRRF','BOX ',NMED,TRRF, 3,IVOLU)
90 *
91 * Define the TRRI volumes
92 *
93 NMED=MN2
94 CALL GSVOLU('TRRI','BOX ',NMED,TRRI, 3,IVOLU)
95 c end ml.
96 *
97 * Define the TRFR volumes
98 *
99 NMED=MCF
100 CALL GSVOLU('TRFR','BOX ',NMED,TRFR, 3,IVOLU)
101 c ml: 12/11/04:
102 c*
103 c* Define the TRFI volumes
104 c*
105 c NMED=MN2
106 c CALL GSVOLU('TRFI','BOX ',NMED,TRFI, 3,IVOLU)
107 *
108 * Define the TRFD volumes
109 *
110 NMED=MCF
111 CALL GSVOLU('TRFD','BOX ',NMED,TRFD, 3,IVOLU)
112 *
113 * Define the TRFU volumes
114 *
115 NMED=MCF
116 CALL GSVOLU('TRFU','BOX ',NMED,TRFU, 3,IVOLU)
117 *
118 * Define the TRFM volumes
119 *
120 NMED=MCF
121 CALL GSVOLU('TRFM','BOX ',NMED,TRFM, 3,IVOLU)
122 *
123 * Define the TRFL volumes
124 *
125 NMED=MCF
126 CALL GSVOLU('TRFL','BOX ',NMED,TRFL, 3,IVOLU)
127 c end ml.
128 *
129 * Define the TRDT volumes
130 *
131 NMED=MAL
132 CALL GSVOLU('TRDT','BOX ',NMED,TRDT, 3,IVOLU)
133 *ml: 10/11/04:
134 *
135 * Positioning the volumes TRAL into mothers TRBS
136 *
137 X=0.
138 Z=0.
139 DO I=1,2
140 Y=(-1)**I*(TRBS(2)-TRAL(2))
141 C # print*,'gptrdv.F: tral: y=',y
142 CALL GSPOS('TRAL',I,'TRBS',X,Y,Z,0,'ONLY')
143 ENDDO
144 *end ml.
145
146 *
147 * Positioning volumes TRSI into mothers TRSO
148 *
149 N= 1
150 X= 0.
151 Y= 0.
152 Z= 0.
153 * CALL GSPOS('TRSI',N,'TRSO',X,Y,Z,0,'ONLY')
154 *Positioning volumes TRSO into mothers TRSI, because now TRSO is included in
155 *TRSI and TRSI is included in TRBS
156 CALL GSPOS('TRSO',N,'TRSI',X,Y,Z,0,'ONLY')
157 *
158 *
159 * Positioning volumes TRSO into mothers TRBS. Remember we have to put
160 * tubes one over each other
161 *
162 Y=0.
163 NUM = 0
164 DO II=1,2
165 #if defined(GPAMELA_UNIX)
166 Z= TRSO(2) * COS(30./180.*ACOS(-1.)) * (-1)**II
167 #endif
168 #if !defined(GPAMELA_UNIX)
169 Z= TRSO(2) * COSD(30.) * (-1)**II
170 #endif
171 DO I=1, 16
172 NUM = NUM + 1
173 X= -TRBS(1) + II*TRSO(2) + (I-1)*2.*TRSO(2)
174 * CALL GSPOS('TRSO',NUM,'TRBS',X,Y,Z,2,'ONLY')
175 *now TRSI is into TRBS (I don't change TRSO(2) in TRSI(2) because they
176 *are equal and the velue of X does not change:
177 CALL GSPOS('TRSI',NUM,'TRBS',X,Y,Z,2,'ONLY')
178 ENDDO
179 ENDDO
180 c ml: 11/11/04:
181 C*
182 C* Positioning volumes TRFI into mothers TRFR
183 C*
184 C N= 1
185 C X= 0.
186 C Y= 0.
187 C Z= 0.
188 C CALL GSPOS('TRFI',N,'TRFR',X,Y,Z,0,'ONLY')
189 *
190 * Positioning volume TRI0 into mother TRR0
191 *
192 N= 1
193 X= 0.
194 Y= 0.
195 c Z= 0.
196 c CALL GSPOS('TRI0',N,'TRR0',X,Y,Z,0,'ONLY')
197 ZTRI0=TRR0(3)-TRI0(3)
198 CALL GSPOS('TRI0',N,'TRR0',X,Y,ZTRI0,0,'MANY')
199 *
200 * Positioning volume TRRI into mother TRRF
201 *
202 N= 1
203 X= 0.
204 Y= 0.
205 Z= 0.
206 CALL GSPOS('TRRI',N,'TRRF',X,Y,Z,0,'ONLY')
207 *
208 * Positioning volume TRRF into mother TRR0
209 *
210 N= 1
211 X= 0.
212 Y= 0.
213 C Z= 0.
214 Z=-TRR0(3)+TRRF(3)
215 CALL GSPOS('TRRF',N,'TRR0',X,Y,Z,0,'ONLY')
216 c end ml.
217 *
218 * Positioning volumes TRAI into mothers TRAN
219 *
220 c ml: 17/11/04:
221 N= 1
222 c X= 0.
223 c Y= TRAN(2)-TRAI(2)
224 X=0.8
225 Y=0.8
226 Z= 0.
227 CALL GSPOS('TRAI',N,'TRAN',X,Y,Z,0,'ONLY')
228 *end ml.
229 *
230 * Positioning volumes TRAI, TRFR, TRBS&TRRA into the mother TRDB
231 *
232 NAN = 0
233 c ml: 12/11/04:
234 c positioning TRRO (frame 0 del TRD)
235 X=0.
236 Y=0.
237 c Z= -TRDB(3) + TRAN(3)
238 Z= -TRDB(3) + TRR0(3)
239 C CALL GSPOS('TRR0',1,'TRDB',X,Y,Z,0,'ONLY')
240 CALL GSPOS('TRR0',1,'TRDB',X,Y,Z,0,'MANY')
241 C Z=Z+TRR0(3)
242 Z=Z+TRR0(3)-0.1
243 M=3
244 num=0
245 DO I=1,4
246 C # print*,'z,ztrfu=',z,ztrfu
247 Z=Z+TRAN(3)
248 ZTRBS=Z
249 c positioning TRAN:
250 c ml:17/11/04:
251 c DO III = 1,2
252 c X = (-1)**(III-1)*TRAN(1)+ (-1)**III*TRDB(1)
253 c Y = -TRAN(2)+ TRDB(2)
254 c NAN = NAN + 1
255 c CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
256 c Y = +TRAN(2)- TRDB(2)
257 c NAN = NAN + 1
258 c CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
259 c ENDDO
260 X = -TRFR(1)+TRAN(1)
261 Y = -TRFR(2)+ TRAN(2)
262 NAN = NAN + 1
263 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
264 X = -TRFR(1)+TRAN(1)
265 Y = +TRFR(2)- TRAN(2)
266 NAN = NAN + 1
267 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,6,'ONLY')
268 X = TRFR(1)-TRAN(1)
269 Y = +TRFR(2)- TRAN(2)
270 NAN = NAN + 1
271 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
272 X = TRFR(1)-TRAN(1)
273 Y = -TRFR(2)+ TRAN(2)
274 NAN = NAN + 1
275 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,1,'ONLY')
276 Z= Z + TRAN(3)
277 c positioning TRBS (the modules):
278 Y=0.
279 DO II=1, M
280 NUM = NUM + 1
281 * shift of modules to have the right overlap:
282 X= (II-1)*2.*TRBS(1) - ( M*TRBS(1) - TRBS(1) ) -
283 + (II-2)*TRSI(2)
284 * now there two different volumes interested at same time:
285 * CALL GSPOS('TRBS',NUM,'TRDB',X,Y,Z,0,'ONLY')
286 CALL GSPOS('TRBS',NUM,'TRDB',X,Y,ZTRBS,0,'MANY')
287 ENDDO
288 c end ml.
289 c positioning TRFD:
290 X=0.
291 ZTRFD=Z-TRFD(3)
292 CALL GSPOS('TRFD',I,'TRDB',X,Y,ZTRFD,0,'MANY')
293 C # print*,'gptrdv: n. of trfd: i=',i
294 c positioning TRFR:
295 Z= Z + TRFR(3)
296 ZRAD=Z
297 CALL GSPOS('TRFR',I,'TRDB',X,Y,Z,0,'MANY')
298 C Z= Z + TRFR(3) + TRBS(3)
299 Z=Z+TRFR(3)
300 c positioning TRFU:
301 ZTRFU= Z + TRFU(3)
302 CALL GSPOS('TRFU',I,'TRDB',X,Y,ZTRFU,0,'MANY')
303 X = 0.
304 Y = 0.
305 cc Z = Z + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3)
306 cc print*,'z del radiatore=',z
307 C # print*,'cos(1+....)=',1 + COS(30./180.*ACOS(-1.))
308 C # Z= Z + 2*TRSO(2) + TRRA(3)
309 c CALL GSPOS('TRRA',I,'TRDB',X,Y,Z,0,'ONLY')
310 CALL GSPOS('TRRA',I,'TRDB',X,Y,ZRAD,0,'ONLY')
311 C # Z= Z - (2*TRSO(2) + TRRA(3)) + TRBS(3)
312 CC Z = Z - ( TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3))
313 CC + + TRBS(3)
314 cc GOTO 151
315 cc DO III = 1,2
316 cc X = (-1)**(III-1)*TRAN(1)+ (-1)**III*TRDB(1)
317 cc Y = -TRAN(2)+ TRDB(2)
318 cc NAN = NAN + 1
319 cc CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
320 cc Y = TRAN(2) - TRDB(2)
321 cc NAN = NAN + 1
322 cc CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
323 cc ENDDO
324 cc X = 0.
325 cc Y = 0.
326 cc Z = Z + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3)
327 C # Z= Z + 2*TRSO(2) + TRRA(3)
328 cc CALL GSPOS('TRRA',I,'TRDB',X,Y,Z,0,'ONLY')
329 C # Z= Z - (2*TRSO(2) + TRRA(3)) + TRBS(3)
330 cc Z = Z - ( TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3))
331 cc + + TRBS(3)
332 ENDDO
333 M=4
334 DO I=1,5
335 Z=Z+TRAN(3)
336 ZTRBS=Z
337 c positioning TRAN:
338 c ml:17/11/04:
339 c DO III = 1,2
340 c X = (-1)**(III-1)*TRAN(1)+ (-1)**III*TRDB(1)
341 c Y = -TRAN(2)+ TRDB(2)
342 c NAN = NAN + 1
343 c CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
344 c Y = +TRAN(2)- TRDB(2)
345 c NAN = NAN + 1
346 c CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
347 c ENDDO
348 X = -TRFR(1)+TRAN(1)
349 Y = -TRFR(2)+ TRAN(2)
350 NAN = NAN + 1
351 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
352 X = -TRFR(1)+TRAN(1)
353 Y = +TRFR(2)- TRAN(2)
354 NAN = NAN + 1
355 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,6,'ONLY')
356 X = TRFR(1)-TRAN(1)
357 Y = +TRFR(2)- TRAN(2)
358 NAN = NAN + 1
359 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
360 X = TRFR(1)-TRAN(1)
361 Y = -TRFR(2)+ TRAN(2)
362 NAN = NAN + 1
363 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,1,'ONLY')
364 Z=Z+TRAN(3)
365 c positioning TRBS (the modules):
366 Y=0.
367 DO II=1, M
368 NUM = NUM + 1
369 * shift of modules to have the right overlap:
370 X= (II-1)*2.*TRBS(1) - ( M*TRBS(1) - TRBS(1) ) -
371 + (II-2)*TRSI(2)
372 * now there two different volumes interested at same time:
373 * CALL GSPOS('TRBS',NUM,'TRDB',X,Y,Z,0,'ONLY')
374 CALL GSPOS('TRBS',NUM,'TRDB',X,Y,ZTRBS,0,'MANY')
375 ENDDO
376 c end ml.
377 c IF((I+4).LE.8)THEN
378 c positioning TRFD:
379 X=0.
380 ZTRFD=Z-TRFD(3)
381 CALL GSPOS('TRFD',I+4,'TRDB',X,Y,ZTRFD,0,'MANY')
382 C # print*,'gptrdv: n. of trfd: i+4=',i+4,ztrfd
383 IF((I+4).LE.8)THEN
384 c positioning TRFR:
385 Z= Z + TRFR(3)
386 ZRAD=Z
387 CALL GSPOS('TRFR',I+4,'TRDB',X,Y,Z,0,'MANY')
388 C Z= Z + TRFR(3) + TRBS(3)
389 Z=Z+TRFR(3)
390 c positioning TRFU:
391 ZTRFU= Z + TRFU(3)
392 CALL GSPOS('TRFU',I+4,'TRDB',X,Y,ZTRFU,0,'MANY')
393 ELSE
394 ZRAD=Z-TRFD(3)+TRFM(3)+TRFL(3)
395 c positioning TRFD:
396 c X=0.
397 c ZTRFD=Z-TRFD(3)
398 c CALL GSPOS('TRFD',I+4,'TRDB',X,Y,ZTRFD,0,'MANY')
399 c print*,'gptrdv: n. of trfd: i+4=',i+4,ztrfd
400 c positioning TRFM:
401 Z= Z + TRFM(3)
402 C ZRAD=Z
403 CALL GSPOS('TRFM',I+4,'TRDB',X,Y,Z,0,'MANY')
404 C Z= Z + TRFR(3) + TRBS(3)
405 Z=Z+TRFM(3)
406 c positioning TRFL:
407 ZTRFL= Z + TRFL(3)
408 CALL GSPOS('TRFL',I+4,'TRDB',X,Y,ZTRFL,0,'MANY')
409 ENDIF
410 X = 0.
411 Y = 0.
412 cc Z = Z + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3)
413 cc print*,'z del radiatore=',z
414 C # print*,'cos(1+....)=',1 + COS(30./180.*ACOS(-1.))
415 C # Z= Z + 2*TRSO(2) + TRRA(3)
416 c CALL GSPOS('TRRA',I,'TRDB',X,Y,Z,0,'ONLY')
417 IF((I+4).LE.8) THEN
418 CALL GSPOS('TRRA',I+4,'TRDB',X,Y,ZRAD,0,'ONLY')
419 ELSE
420 CALL GSPOS('TRR2',I+4,'TRDB',X,Y,ZRAD,0,'ONLY')
421 ENDIF
422 ENDDO
423 goto 151
424 M=4
425 DO I=1,5
426 X= 0.
427 Z= Z + TRFR(3)
428 CALL GSPOS('TRFR',(I+4),'TRDB',X,Y,Z,0,'ONLY')
429 Z= Z + TRFR(3) + TRBS(3)
430 DO II=1, M
431 NUM = NUM + 1
432 *shift of modules to have the right overlap:
433 X= (II-1)*2.*TRBS(1) - ( M*TRBS(1) - TRBS(1) )
434 + + (3/2 -(II-1))*TRSI(2)
435 *now there two different volumes interested at same time:
436 * CALL GSPOS('TRBS',NUM,'TRDB',X,Y,Z,0,'ONLY')
437 CALL GSPOS('TRBS',NUM,'TRDB',X,Y,Z,0,'MANY')
438 ENDDO
439 DO III = 1,2
440 X = (-1)**(III-1)*TRAN(1)+ (-1)**III*TRDB(1)
441 Y = -TRAN(2)+ TRDB(2)
442 NAN = NAN + 1
443 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
444 Y = TRAN(2) - TRDB(2)
445 NAN = NAN + 1
446 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
447 ENDDO
448 X= 0.
449 Y= 0.
450 c ml: 12/11/04:
451 IF((I+4).LE.8) THEN
452 c end ml.
453 Z = Z + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3)
454 CALL GSPOS('TRRA',(I+4),'TRDB',X,Y,Z,0,'ONLY')
455 Z = Z - (TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRRA(3) )
456 + + TRBS(3)
457 c ml:
458 ELSE
459 *
460 * Positioning an extra radiator plane on top
461 *
462 Z = Z + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.))) + TRR2(3)
463 NUM=1
464 CALL GSPOS('TRR2',NUM,'TRDB',X,Y,Z,0,'ONLY')
465 Z = Z + TRBS(3) -( TRSO(2)*( 1 + COS(30./180.*ACOS(-1.)))
466 + + 3*TRR2(3) )
467 ENDIF
468 C end ml.
469 ENDDO
470 c ml: 12/11/04:
471 C*
472 C* Positioning an extra radiator plane on top
473 C*
474 C Z = Z - TRBS(3) + TRSO(2)*( 1 + COS(30./180.*ACOS(-1.)))
475 C + + 3*TRRA(3)
476 C CALL GSPOS('TRRA',NUM,'TRDB',X,Y,Z,0,'ONLY')
477 C Z = Z + TRBS(3) -( TRSO(2)*( 1 + COS(30./180.*ACOS(-1.)))
478 C + + 3*TRRA(3) )
479 C end ml.
480 *
481 * Positioning the TOP frame
482 *
483 X = 0.
484 Y = 0.
485 Z = Z + TRFR(3)
486 CALL GSPOS('TRFR',10,'TRDB',X,Y,Z,0,'ONLY')
487 *
488 * Positioning the angular pieces to hold the TOF. TRAN & TRDT
489 *
490 Z = Z + TRFR(3) + TRAN(3)
491 DO I = 1,2
492 X = (-1)**(I-1)*TRAN(1)+ (-1)**I*TRDB(1)
493 Y = -TRAN(2)+ TRDB(2)
494 NAN = NAN + 1
495 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,0,'ONLY')
496 Y = +TRAN(2)- TRDB(2)
497 NAN = NAN + 1
498 CALL GSPOS('TRAN',NAN,'TRDB',X,Y,Z,4,'ONLY')
499 ENDDO
500 Z = Z + TRAN(3) + TRDT(3)
501 NDT = 0
502 DO I = 1,2
503 X = (-1)**(I-1)*(2*TRAN(1)-TRDT(1))+ (-1)**I*TRDB(1)
504 Y = -(2*TRAN(2)-TRDT(2)) + TRDB(2)
505 NDT = NDT + 1
506 CALL GSPOS('TRDT',NDT,'TRDB',X,Y,Z,0,'ONLY')
507 Y = +(2*TRAN(2)-TRDT(2)) - TRDB(2)
508 NDT = NDT + 1
509 CALL GSPOS('TRDT',NDT,'TRDB',X,Y,Z,0,'ONLY')
510 ENDDO
511 151 continue
512 RETURN
513 END

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