/[PAMELA software]/DarthVader/TrackerLevel2/src/F77/functionspfa.f
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Contents of /DarthVader/TrackerLevel2/src/F77/functionspfa.f

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Revision 1.2 - (show annotations) (download)
Tue May 30 16:30:37 2006 UTC (18 years, 6 months ago) by pam-fi
Branch: MAIN
CVS Tags: v0r02, v1r01beta, v1r00, v1r01, v2r00BETA
Changes since 1.1: +8 -8 lines
Error handling from F77 routine / Fixed some bugs with default calibration

1 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
2 * this file contains all subroutines and functions
3 * that are needed for position finding algorithms
4 *
5 *
6 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
7
8
9 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
10 real function pfa_eta(ic,angle)
11 *--------------------------------------------------------------
12 * this function returns the position (in strip units)
13 * it calls:
14 * - pfa_eta2(ic,angle)
15 * - pfa_eta3(ic,angle)
16 * - pfa_eta4(ic,angle)
17 * according to the angle
18 *--------------------------------------------------------------
19 include 'commontracker.f'
20 c include 'calib.f'
21 include 'level1.f'
22
23 pfa_eta = 0
24
25 if(mod(int(VIEW(ic)),2).eq.1)then !Y-view
26
27 pfa_eta = pfa_eta2(ic,angle)
28
29 else !X-view
30
31 if(abs(angle).le.10.)then
32 pfa_eta = pfa_eta2(ic,angle)
33 elseif(abs(angle).gt.10..and.abs(angle).le.15.)then
34 pfa_eta = pfa_eta3(ic,angle)
35 elseif(abs(angle).gt.15.)then
36 pfa_eta = pfa_eta4(ic,angle)
37 endif
38
39 endif
40
41
42 100 return
43 end
44
45 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
46 real function ris_eta(ic,angle)
47 *--------------------------------------------------------------
48 * this function returns the average spatial resolution
49 * (in cm) for the ETA algorithm (function pfa_eta(ic,angle))
50 * it calls:
51 * - risx_eta2(angle)
52 * - risy_eta2(angle)
53 * - risx_eta3(angle)
54 * - risx_eta4(angle)
55 * according to the angle
56 *--------------------------------------------------------------
57 include 'commontracker.f'
58 c include 'calib.f'
59 include 'level1.f'
60
61 c$$$ logical DEBUG
62 c$$$ common/dbg/DEBUG
63
64 ris_eta = 0
65
66 if(mod(int(VIEW(ic)),2).eq.1)then !Y-view
67
68 ris_eta = risy_eta2(angle)
69 if(abs(angle).gt.21.)ris_eta = risy_eta2(21.)
70
71 else !X-view
72
73 if(abs(angle).le.10.)then
74 ris_eta = risx_eta2(angle)
75 elseif(abs(angle).gt.10..and.abs(angle).le.15.)then
76 ris_eta = risx_eta3(angle)
77 elseif(abs(angle).gt.15..and.abs(angle).le.21.)then
78 ris_eta = risx_eta4(angle)
79 elseif(abs(angle).gt.21.)then
80 ris_eta = risx_eta4(21.)
81 endif
82
83 endif
84
85 c$$$ if(DEBUG)print*,'ris (ic ',ic,' ang',angle,')'
86 c$$$ $ ,' -->',ris_eta
87
88
89 100 return
90 end
91
92 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
93 real function fbad_eta(ic,angle)
94 *-------------------------------------------------------
95 * this function returns a factor that takes into
96 * account deterioration of the spatial resolution
97 * in the case BAD strips are included in the cluster.
98 * This factor should multiply the nominal spatial
99 * resolution.
100 * It calls the function FBAD_COG(NCOG,IC),
101 * accordingto the angle
102 *-------------------------------------------------------
103
104 include 'commontracker.f'
105 include 'level1.f'
106 * include 'calib.f'
107 fbad_eta = 0
108
109 if(mod(int(VIEW(ic)),2).eq.1)then !Y-view
110
111 fbad_eta = fbad_cog(2,ic)
112
113 else !X-view
114
115 if(abs(angle).le.10.)then
116 fbad_eta = fbad_cog(2,ic)
117 elseif(abs(angle).gt.10..and.abs(angle).le.15.)then
118 fbad_eta = fbad_cog(3,ic)
119 elseif(abs(angle).gt.15.)then
120 fbad_eta = fbad_cog(4,ic)
121 endif
122
123 endif
124
125 return
126 end
127
128 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
129 c*****************************************************
130 cccccc 02/02/2006 modified by Elena Vannuccini --> (1)
131 c*****************************************************
132 c real function pfa_eta2(cog2,view,lad,angle)
133 real function pfa_eta2(ic,angle) !(1)
134 *--------------------------------------------------------------
135 * this function returns
136 *
137 * - the position (in strip units)
138 * corrected according to the ETA2 Position Finding Algorithm.
139 * The function performs an interpolation of FETA2%ETA2
140 *
141 * - if the angle is out of range, the calibration parameters
142 * of the lowest or higher bin are used
143 *
144 *--------------------------------------------------------------
145 include 'commontracker.f'
146 include 'calib.f'
147 include 'level1.f'
148
149 real cog2,angle
150 integer iview,lad
151
152 c logical DEBUG
153 c common/dbg/DEBUG
154
155 iview = VIEW(ic) !(1)
156 lad = nld(MAXS(ic),VIEW(ic)) !(1)
157 cog2 = cog(2,ic) !(1)
158 pfa_eta2=cog2
159
160 * find angular bin
161 * (in futuro possiamo pensare di interpolare anche sull'angolo)
162 do iang=1,nangbin
163 c print*,'~~~~~~~~~~~~ ',iang,angL(iang),angR(iang),angle
164 if(angL(iang).lt.angle.and.angR(iang).ge.angle)then
165 iangle=iang
166 goto 98
167 endif
168 enddo
169 if(DEBUG)
170 $ print*,'pfa_eta2 *** warning *** angle out of range: ',angle
171 if(angle.lt.angL(1))iang=1
172 if(angle.gt.angR(nangbin))iang=nangbin
173 98 continue !jump here if ok
174
175
176 c$$$* find extremes of interpolation
177 c$$$ iflag=0
178 c$$$* --------------------------------
179 c$$$ if(cog2.lt.eta2(1,iang).or.cog2.gt.eta2(netaval,iang))then
180 c$$$c print*,'pfa_eta2 *** warning *** argument out of range: ',cog2
181 c$$$* goto 100
182 c$$$* ----------------------------------------------
183 c$$$* non salto piu`, ma scalo di 1 o -1
184 c$$$* nel caso si tratti di un cluster
185 c$$$* in cui la strip con il segnale massimo non coincide
186 c$$$* con la strip con il rapposto s/n massimo!!!
187 c$$$* ----------------------------------------------
188 c$$$ if(cog2.lt.eta2(1,iang))then !temp
189 c$$$ cog2=cog2+1. !temp
190 c$$$ iflag=1 !temp
191 c$$$ else !temp
192 c$$$ cog2=cog2-1. !temp
193 c$$$ iflag=-1 !temp
194 c$$$ endif !temp
195 c$$$c print*,'shifted >>> ',cog2
196 c$$$ endif
197
198 iadd=0
199 10 continue
200 if(cog2.lt.eta2(1,iang))then
201 cog2 = cog2 + 1
202 iadd = iadd + 1
203 goto 10
204 endif
205 20 continue
206 if(cog2.gt.eta2(netaval,iang))then
207 cog2 = cog2 - 1
208 iadd = iadd - 1
209 goto 20
210 endif
211
212 * --------------------------------
213 c print*,'*****',i,view,lad,iang,'------> cog2 ',cog2
214 do i=2,netaval
215 if(eta2(i,iang).gt.cog2)then
216
217 x1 = eta2(i-1,iang)
218 x2 = eta2(i,iang)
219 y1 = feta2(i-1,iview,lad,iang)
220 y2 = feta2(i,iview,lad,iang)
221
222 c print*,'*****',i,view,lad,iang
223 c print*,'-----',x1,x2,y1,y2
224 goto 99
225 endif
226 enddo
227 99 continue
228
229
230 AA=(y2-y1)/(x2-x1)
231 BB=y1-AA*x1
232
233 pfa_eta2 = AA*cog2+BB
234 pfa_eta2 = pfa_eta2 - iadd
235
236 c$$$ if(iflag.eq.1)then
237 c$$$ pfa_eta2=pfa_eta2-1. !temp
238 c$$$ cog2=cog2-1. !temp
239 c$$$ endif
240 c$$$ if(iflag.eq.-1)then
241 c$$$ pfa_eta2=pfa_eta2+1. !temp
242 c$$$ cog2=cog2+1. !temp
243 c$$$ endif
244
245 if(DEBUG)print*,'ETA2 (ic ',ic,' ang',angle,')'
246 $ ,cog2-iadd,' -->',pfa_eta2
247
248
249 100 return
250 end
251
252 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
253 c*****************************************************
254 cccccc 02/02/2006 modified by Elena Vannuccini --> (1)
255 c*****************************************************
256 c real function pfa_eta3(cog3,view,lad,angle)
257 real function pfa_eta3(ic,angle) !(1)
258 *--------------------------------------------------------------
259 * this function returns
260 *
261 * - the position (in strip units)
262 * corrected according to the ETA3 Position Finding Algorithm.
263 * The function performs an interpolation of FETA3%ETA3
264 *
265 * - if the angle is out of range, the calibration parameters
266 * of the lowest or higher bin are used
267 *
268 *--------------------------------------------------------------
269 include 'commontracker.f'
270 include 'calib.f'
271 include 'level1.f'
272
273 real cog3,angle
274 integer iview,lad
275
276 c logical DEBUG
277 c common/dbg/DEBUG
278
279
280 iview = VIEW(ic) !(1)
281 lad = nld(MAXS(ic),VIEW(ic)) !(1)
282 cog3 = cog(3,ic) !(1)
283 pfa_eta3=cog3
284
285 * find angular bin
286 * (in futuro possiamo pensare di interpolare anche sull'angolo)
287 do iang=1,nangbin
288 c print*,'~~~~~~~~~~~~ ',iang,angL(iang),angR(iang),angle
289 if(angL(iang).lt.angle.and.angR(iang).ge.angle)then
290 iangle=iang
291 goto 98
292 endif
293 enddo
294 if(DEBUG)
295 $ print*,'pfa_eta3 *** warning *** angle out of range: ',angle
296 if(angle.lt.angL(1))iang=1
297 if(angle.gt.angR(nangbin))iang=nangbin
298 98 continue !jump here if ok
299
300
301 c$$$* find extremes of interpolation
302 c$$$ iflag=0
303 c$$$* --------------------------------
304 c$$$ if(cog3.lt.eta3(1,iang).or.cog3.gt.eta3(netaval,iang))then
305 c$$$* ----------------------------------------------
306 c$$$* non salto piu`, ma scalo di 1 o -1
307 c$$$* nel caso si tratti di un cluster
308 c$$$* in cui la strip con il segnale massimo non coincide
309 c$$$* con la strip con il rapposto s/n massimo!!!
310 c$$$* ----------------------------------------------
311 c$$$ if(cog2.lt.eta2(1,iang))then !temp
312 c$$$ cog2=cog2+1. !temp
313 c$$$ iflag=1 !temp
314 c$$$ else !temp
315 c$$$ cog2=cog2-1. !temp
316 c$$$ iflag=-1 !temp
317 c$$$ endif !temp
318 c$$$c print*,'shifted >>> ',cog2
319 c$$$ endif
320
321
322 iadd=0
323 10 continue
324 if(cog3.lt.eta3(1,iang))then
325 cog3 = cog3 + 1
326 iadd = iadd + 1
327 goto 10
328 endif
329 20 continue
330 if(cog3.gt.eta3(netaval,iang))then
331 cog3 = cog3 - 1
332 iadd = iadd - 1
333 goto 20
334 endif
335
336 * --------------------------------
337 c print*,'*****',i,view,lad,iang,'------> cog2 ',cog2
338 do i=2,netaval
339 if(eta3(i,iang).gt.cog3)then
340
341 x1 = eta3(i-1,iang)
342 x2 = eta3(i,iang)
343 y1 = feta3(i-1,iview,lad,iang)
344 y2 = feta3(i,iview,lad,iang)
345
346 c print*,'*****',i,view,lad,iang
347 c print*,'-----',x1,x2,y1,y2
348 goto 99
349 endif
350 enddo
351 99 continue
352
353
354 AA=(y2-y1)/(x2-x1)
355 BB=y1-AA*x1
356
357 pfa_eta3 = AA*cog3+BB
358 pfa_eta3 = pfa_eta3 - iadd
359
360 c$$$ if(iflag.eq.1)then
361 c$$$ pfa_eta2=pfa_eta2-1. !temp
362 c$$$ cog2=cog2-1. !temp
363 c$$$ endif
364 c$$$ if(iflag.eq.-1)then
365 c$$$ pfa_eta2=pfa_eta2+1. !temp
366 c$$$ cog2=cog2+1. !temp
367 c$$$ endif
368
369 if(DEBUG)print*,'ETA3 (ic ',ic,' ang',angle,')'
370 $ ,cog3-iadd,' -->',pfa_eta3
371
372 100 return
373 end
374
375 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
376 c*****************************************************
377 cccccc 02/02/2006 modified by Elena Vannuccini --> (1)
378 c*****************************************************
379 c real function pfa_eta4(cog4,view,lad,angle)
380 real function pfa_eta4(ic,angle) !(1)
381 *--------------------------------------------------------------
382 * this function returns
383 *
384 * - the position (in strip units)
385 * corrected according to the ETA4 Position Finding Algorithm.
386 * The function performs an interpolation of FETA3%ETA3
387 *
388 * - if the angle is out of range, the calibration parameters
389 * of the lowest or higher bin are used
390 *
391 *--------------------------------------------------------------
392 include 'commontracker.f'
393 include 'calib.f'
394 include 'level1.f'
395
396 real cog4,angle
397 integer iview,lad
398
399 c logical DEBUG
400 c common/dbg/DEBUG
401
402 iview = VIEW(ic) !(1)
403 lad = nld(MAXS(ic),VIEW(ic)) !(1)
404 cog4=cog(4,ic) !(1)
405 pfa_eta4=cog4
406
407 * find angular bin
408 * (in futuro possiamo pensare di interpolare anche sull'angolo)
409 do iang=1,nangbin
410 c print*,'~~~~~~~~~~~~ ',iang,angL(iang),angR(iang),angle
411 if(angL(iang).lt.angle.and.angR(iang).ge.angle)then
412 iangle=iang
413 goto 98
414 endif
415 enddo
416 if(DEBUG)
417 $ print*,'pfa_eta4 *** warning *** angle out of range: ',angle
418 if(angle.lt.angL(1))iang=1
419 if(angle.gt.angR(nangbin))iang=nangbin
420 98 continue !jump here if ok
421
422
423 c$$$* find extremes of interpolation
424 c$$$ iflag=0
425 c$$$* --------------------------------
426 c$$$ if(cog3.lt.eta3(1,iang).or.cog3.gt.eta3(netaval,iang))then
427 c$$$* ----------------------------------------------
428 c$$$* non salto piu`, ma scalo di 1 o -1
429 c$$$* nel caso si tratti di un cluster
430 c$$$* in cui la strip con il segnale massimo non coincide
431 c$$$* con la strip con il rapposto s/n massimo!!!
432 c$$$* ----------------------------------------------
433 c$$$ if(cog2.lt.eta2(1,iang))then !temp
434 c$$$ cog2=cog2+1. !temp
435 c$$$ iflag=1 !temp
436 c$$$ else !temp
437 c$$$ cog2=cog2-1. !temp
438 c$$$ iflag=-1 !temp
439 c$$$ endif !temp
440 c$$$c print*,'shifted >>> ',cog2
441 c$$$ endif
442
443
444 iadd=0
445 10 continue
446 if(cog4.lt.eta4(1,iang))then
447 cog4 = cog4 + 1
448 iadd = iadd + 1
449 goto 10
450 endif
451 20 continue
452 if(cog4.gt.eta4(netaval,iang))then
453 cog4 = cog4 - 1
454 iadd = iadd - 1
455 goto 20
456 endif
457
458 * --------------------------------
459 c print*,'*****',i,view,lad,iang,'------> cog2 ',cog2
460 do i=2,netaval
461 if(eta4(i,iang).gt.cog4)then
462
463 x1 = eta4(i-1,iang)
464 x2 = eta4(i,iang)
465 y1 = feta4(i-1,iview,lad,iang)
466 y2 = feta4(i,iview,lad,iang)
467
468 c print*,'*****',i,view,lad,iang
469 c print*,'-----',x1,x2,y1,y2
470 goto 99
471 endif
472 enddo
473 99 continue
474
475
476 AA=(y2-y1)/(x2-x1)
477 BB=y1-AA*x1
478
479 pfa_eta4 = AA*cog4+BB
480 pfa_eta4 = pfa_eta4 - iadd
481
482 c$$$ if(iflag.eq.1)then
483 c$$$ pfa_eta2=pfa_eta2-1. !temp
484 c$$$ cog2=cog2-1. !temp
485 c$$$ endif
486 c$$$ if(iflag.eq.-1)then
487 c$$$ pfa_eta2=pfa_eta2+1. !temp
488 c$$$ cog2=cog2+1. !temp
489 c$$$ endif
490
491 if(DEBUG)print*,'ETA4 (ic ',ic,' ang',angle,')'
492 $ ,cog4-iadd,' -->',pfa_eta4
493
494 100 return
495 end
496
497
498
499 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
500 real function cog0(ncog,ic)
501 *-------------------------------------------------
502 * this function returns
503 *
504 * - the Center-Of-Gravity of the cluster IC
505 * evaluated using NCOG strips,
506 * calculated relative to MAXS(IC)
507 *
508 * - zero in case that not enough strips
509 * have a positive signal
510 *
511 * NOTE:
512 * This is the old definition, used by Straulino.
513 * The new routine, according to Landi,
514 * is COG(NCOG,IC)
515 *-------------------------------------------------
516
517
518 include 'commontracker.f'
519 include 'level1.f'
520
521 * --> signal of the central strip
522 sc = CLSIGNAL(INDMAX(ic)) !center
523
524 * signal of adjacent strips
525 * --> left
526 sl1 = 0 !left 1
527 if(
528 $ (INDMAX(ic)-1).ge.INDSTART(ic)
529 $ )
530 $ sl1 = max(0.,CLSIGNAL(INDMAX(ic)-1))
531
532 sl2 = 0 !left 2
533 if(
534 $ (INDMAX(ic)-2).ge.INDSTART(ic)
535 $ )
536 $ sl2 = max(0.,CLSIGNAL(INDMAX(ic)-2))
537
538 * --> right
539 sr1 = 0 !right 1
540 if(
541 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+1).lt.INDSTART(ic+1))
542 $ .or.
543 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+1).le.TOTCLLENGTH)
544 $ )
545 $ sr1 = max(0.,CLSIGNAL(INDMAX(ic)+1))
546
547 sr2 = 0 !right 2
548 if(
549 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+2).lt.INDSTART(ic+1))
550 $ .or.
551 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+2).le.TOTCLLENGTH)
552 $ )
553 $ sr2 = max(0.,CLSIGNAL(INDMAX(ic)+2))
554
555 ************************************************************
556 * COG computation
557 ************************************************************
558
559 c print*,sl2,sl1,sc,sr1,sr2
560
561 COG = 0.
562
563 if(sl1.gt.sr1.and.sl1.gt.0.)then
564
565 if(ncog.eq.2.and.sl1.ne.0)then
566 COG = -sl1/(sl1+sc)
567 elseif(ncog.eq.3.and.sl1.ne.0.and.sr1.ne.0)then
568 COG = (sr1-sl1)/(sl1+sc+sr1)
569 elseif(ncog.eq.4.and.sl1.ne.0.and.sr1.ne.0.and.sl2.ne.0)then
570 COG = (sr1-sl1-2*sl2)/(sl2+sl1+sc+sr1)
571 else
572 COG = 0.
573 endif
574
575 elseif(sl1.le.sr1.and.sr1.gt.0.)then
576
577 if(ncog.eq.2.and.sr1.ne.0)then
578 COG = sr1/(sc+sr1)
579 elseif(ncog.eq.3.and.sr1.ne.0.and.sl1.ne.0)then
580 COG = (sr1-sl1)/(sl1+sc+sr1)
581 elseif(ncog.eq.4.and.sr1.ne.0.and.sl1.ne.0.and.sr2.ne.0)then
582 COG = (2*sr2+sr1-sl1)/(sl2+sl1+sc+sr1)
583 else
584 COG = 0.
585 endif
586
587 endif
588
589 COG0 = COG
590
591 c print *,ncog,ic,cog,'/////////////'
592
593 return
594 end
595
596 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
597 real function cog(ncog,ic)
598 *-------------------------------------------------
599 * this function returns
600 *
601 * - if NCOG=0, the Center-Of-Gravity of the
602 * cluster IC, relative to MAXS(IC), according to
603 * the cluster multiplicity
604 *
605 * - if NCOG>0, the Center-Of-Gravity of the cluster IC
606 * evaluated using NCOG strips, even if they have a
607 * negative signal (according to Landi)
608 *
609 *-------------------------------------------------
610
611
612 include 'commontracker.f'
613 include 'calib.f'
614 include 'level1.f'
615
616 c logical DEBUG
617 c common/dbg/DEBUG
618
619
620 if (ncog.gt.0) then
621 * ===========================
622 * ETA2 ETA3 ETA4 computation
623 * ===========================
624
625 * --> signal of the central strip
626 sc = CLSIGNAL(INDMAX(ic)) !center
627 * signal of adjacent strips
628 sl1 = 0 !left 1
629 if(
630 $ (INDMAX(ic)-1).ge.INDSTART(ic)
631 $ )
632 $ sl1 = CLSIGNAL(INDMAX(ic)-1)
633
634 sl2 = 0 !left 2
635 if(
636 $ (INDMAX(ic)-2).ge.INDSTART(ic)
637 $ )
638 $ sl2 = CLSIGNAL(INDMAX(ic)-2)
639
640 sr1 = 0 !right 1
641 if(
642 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+1).lt.INDSTART(ic+1))
643 $ .or.
644 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+1).le.TOTCLLENGTH)
645 $ )
646 $ sr1 = CLSIGNAL(INDMAX(ic)+1)
647
648 sr2 = 0 !right 2
649 if(
650 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+2).lt.INDSTART(ic+1))
651 $ .or.
652 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+2).le.TOTCLLENGTH)
653 $ )
654 $ sr2 = CLSIGNAL(INDMAX(ic)+2)
655
656 COG = 0.
657
658 if(ncog.eq.2)then
659 if(sl1.gt.sr1)then
660 COG = -sl1/(sl1+sc)
661 elseif(sl1.le.sr1)then
662 COG = sr1/(sc+sr1)
663 endif
664 elseif(ncog.eq.3)then
665 COG = (sr1-sl1)/(sl1+sc+sr1)
666 elseif(ncog.eq.4)then
667 if(sl2.gt.sr2)then
668 COG = (sr1-sl1-2*sl2)/(sl2+sl1+sc+sr1)
669 elseif(sl2.le.sr2)then
670 COG = (2*sr2+sr1-sl1)/(sl2+sl1+sc+sr1)
671 endif
672 else
673 print*,'function COG(NCOG,IC) ==> WARNING!! NCOG=',NCOG
674 print*,' (NCOG must be <= 4)'
675 COG = 0.
676 endif
677
678 c print*,'NCOG ',ncog,ic,' @@@ ',sl1,sc,sr1,' @@@ ',cog
679
680 elseif(ncog.eq.0)then
681 * =========================
682 * COG computation
683 * =========================
684
685 iv=VIEW(ic)
686 if(mod(iv,2).eq.1)incut=incuty
687 if(mod(iv,2).eq.0)incut=incutx
688
689 istart=INDSTART(IC)
690 istop=TOTCLLENGTH
691 if(ic.lt.NCLSTR1)istop=INDSTART(IC+1)-1
692 COG=0
693 mu=0
694 do i=istart,istop
695 ipos=i-INDMAX(ic)
696 ivk=nvk(MAXS(ic)+ipos)
697 is=nst(MAXS(ic)+ipos)
698 * print*,'******************',istart,istop,ipos
699 * $ ,MAXS(ic)+ipos,iv,ivk,is
700 cut=incut*SIGMA(iv,ivk,is)
701 if(CLSIGNAL(i).ge.cut)then
702 COG = COG + ipos*CLSIGNAL(i)
703 mu = mu + 1
704 c print*,ipos,CLSIGNAL(i),incut,cut
705 endif
706 enddo
707 COG=COG/DEDX(ic)
708 c if(DEBUG)print*,'COG (ic ',ic,' m',mu,')'
709 c $ ,cog
710
711 else
712
713 COG=0
714 print*,'function COG(NCOG,IC) ==> WARNING!! NCOG=',NCOG
715 print*,' (NCOG must be >= 0)'
716
717
718 endif
719
720 c print *,ncog,ic,cog,'/////////////'
721
722 return
723 end
724
725 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
726 real function fbad_cog(ncog,ic)
727 *-------------------------------------------------------
728 * this function returns a factor that takes into
729 * account deterioration of the spatial resolution
730 * in the case BAD strips are included in the cluster.
731 * This factor should multiply the nominal spatial
732 * resolution.
733 *
734 *-------------------------------------------------------
735
736 include 'commontracker.f'
737 include 'level1.f'
738 include 'calib.f'
739
740 if(mod(int(VIEW(ic)),2).eq.1)then !Y-view
741 f = 4.
742 si = 8.4
743 incut=incuty
744 else !X-view
745 f = 6.
746 si = 3.9
747 incut=incutx
748 endif
749
750 fbad_cog = 1.
751
752 if (ncog.gt.0) then
753
754 * --> signal of the central strip
755 sc = CLSIGNAL(INDMAX(ic)) !center
756 fsc = 1
757 if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)) ).eq.0)fsc=f
758 * --> signal of adjacent strips
759 sl1 = 0 !left 1
760 fsl1 = 1 !left 1
761 if(
762 $ (INDMAX(ic)-1).ge.INDSTART(ic)
763 $ )then
764 sl1 = CLSIGNAL(INDMAX(ic)-1)
765 if(BAD(VIEW(ic),nvk(MAXS(ic)-1),nst(MAXS(ic)-1)).eq.0)fsl1=f
766 c else
767 c fsl1 = 0
768 endif
769
770 sl2 = 0 !left 2
771 fsl2 = 1 !left 2
772 if(
773 $ (INDMAX(ic)-2).ge.INDSTART(ic)
774 $ )then
775 sl2 = CLSIGNAL(INDMAX(ic)-2)
776 if(BAD(VIEW(ic),nvk(MAXS(ic)-2),nst(MAXS(ic)-2)).eq.0)fsl2=f
777 c else
778 c fsl2 = 0
779 endif
780 sr1 = 0 !right 1
781 fsr1 = 1 !right 1
782 if(
783 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+1).lt.INDSTART(ic+1))
784 $ .or.
785 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+1).le.TOTCLLENGTH)
786 $ )then
787 sr1 = CLSIGNAL(INDMAX(ic)+1)
788 if(BAD(VIEW(ic),nvk(MAXS(ic)+1),nst(MAXS(ic)+1)).eq.0)fsr1=f
789 c else
790 c fsr1 = 0
791 endif
792 sr2 = 0 !right 2
793 fsr2 = 1 !right 2
794 if(
795 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+2).lt.INDSTART(ic+1))
796 $ .or.
797 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+2).le.TOTCLLENGTH)
798 $ )then
799 sr2 = CLSIGNAL(INDMAX(ic)+2)
800 if(BAD(VIEW(ic),nvk(MAXS(ic)+2),nst(MAXS(ic)+2)).eq.0)fsr2=f
801 c else
802 c fsr2 = 0
803 endif
804
805
806
807 ************************************************************
808 * COG computation
809 ************************************************************
810
811 c print*,sl2,sl1,sc,sr1,sr2
812
813 COG = 0.
814
815 if(ncog.eq.2)then
816 if(sl1.gt.sr1)then
817 COG = -sl1/(sl1+sc)
818 fbad_cog = (fsl1*(-1-COG)**2+fsc*(-COG)**2)
819 fbad_cog = fbad_cog / ((-1-COG)**2+(-COG)**2)
820 elseif(sl1.le.sr1)then
821 COG = sr1/(sc+sr1)
822 fbad_cog = (fsc*(-COG)**2+fsr1*(1-COG)**2)
823 fbad_cog = fbad_cog / ((-COG)**2+(1-COG)**2)
824 endif
825 elseif(ncog.eq.3)then
826 COG = (sr1-sl1)/(sl1+sc+sr1)
827 fbad_cog =
828 $ (fsl1*(-1-COG)**2+fsc*(-COG)**2+fsr1*(1-COG)**2)
829 fbad_cog =
830 $ fbad_cog / ((-1-COG)**2+(-COG)**2+(1-COG)**2)
831 elseif(ncog.eq.4)then
832 if(sl2.gt.sr2)then
833 COG = (sr1-sl1-2*sl2)/(sl2+sl1+sc+sr1)
834 fbad_cog =
835 $ (fsl2*(-2-COG)**2+fsl1*(-1-COG)**2
836 $ +fsc*(-COG)**2+fsr1*(1-COG)**2)
837 fbad_cog =
838 $ fbad_cog / ((-2-COG)**2+(-1-COG)**2
839 $ +(-COG)**2+(1-COG)**2)
840 elseif(sl2.le.sr2)then
841 COG = (2*sr2+sr1-sl1)/(sl2+sl1+sc+sr1)
842 fbad_cog =
843 $ (fsl1*(-1-COG)**2
844 $ +fsc*(-COG)**2+fsr1*(1-COG)**2+fsr2*(2-COG)**2)
845 fbad_cog =
846 $ fbad_cog / ((-1-COG)**2
847 $ +(-COG)**2+(1-COG)**2+(2-COG)**2)
848 endif
849 else
850 print*,'function FBAD_COG(NCOG,IC) ==> WARNING!! NCOG=',NCOG
851 print*,' (NCOG must be <= 4)'
852 COG = 0.
853 endif
854
855 elseif(ncog.eq.0)then
856
857
858 iv=VIEW(ic)
859 istart=INDSTART(IC)
860 istop=TOTCLLENGTH
861 if(ic.lt.NCLSTR1)istop=INDSTART(IC+1)-1
862 COG=0.
863 SNU=0.
864 SDE=0.
865 do i=istart,istop
866 ipos=i-INDMAX(ic)
867 il=nvk(MAXS(ic)+ipos)
868 is=nst(MAXS(ic)+ipos)
869 cut=incut*SIGMA(iv,il,is)
870 if(CLSIGNAL(i).gt.cut)then
871 COG = COG + ipos*CLSIGNAL(i)
872 endif
873 enddo
874 COG=COG/DEDX(ic)
875 do i=istart,istop
876 ipos=i-INDMAX(ic)
877 il=nvk(MAXS(ic)+ipos)
878 is=nst(MAXS(ic)+ipos)
879 cut=incut*SIGMA(iv,il,is)
880 if(CLSIGNAL(i).gt.cut)then
881 fs=1
882 if(BAD(iv,il,is).eq.0)fs=f
883 SNU = SNU + fs*(ipos-COG)**2
884 SDE = SDE + (ipos-COG)**2
885 endif
886 enddo
887 if(SDE.ne.0)FBAD_COG=SNU/SDE
888
889 else
890
891 FBAD_COG=0
892 print*,'function FBAD_COG(NCOG,IC) ==> WARNING!! NCOG=',NCOG
893 print*,' (NCOG must be >= 0)'
894
895
896 endif
897
898
899 fbad_cog = sqrt(fbad_cog)
900
901 return
902 end
903
904
905 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
906 real function fbad_cog0(ncog,ic)
907 *-------------------------------------------------------
908 * this function returns a factor that takes into
909 * account deterioration of the spatial resolution
910 * in the case BAD strips are included in the cluster.
911 * This factor should multiply the nominal spatial
912 * resolution.
913 *
914 * NB!!!
915 * (this is the old version. It consider only the two
916 * strips with the greatest signal. The new one is
917 * fbad_cog(ncog,ic) )
918 *
919 *-------------------------------------------------------
920
921 include 'commontracker.f'
922 include 'level1.f'
923 include 'calib.f'
924
925 * --> signal of the central strip
926 sc = CLSIGNAL(INDMAX(ic)) !center
927
928 * signal of adjacent strips
929 * --> left
930 sl1 = 0 !left 1
931 if(
932 $ (INDMAX(ic)-1).ge.INDSTART(ic)
933 $ )
934 $ sl1 = max(0.,CLSIGNAL(INDMAX(ic)-1))
935
936 sl2 = 0 !left 2
937 if(
938 $ (INDMAX(ic)-2).ge.INDSTART(ic)
939 $ )
940 $ sl2 = max(0.,CLSIGNAL(INDMAX(ic)-2))
941
942 * --> right
943 sr1 = 0 !right 1
944 if(
945 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+1).lt.INDSTART(ic+1))
946 $ .or.
947 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+1).le.TOTCLLENGTH)
948 $ )
949 $ sr1 = max(0.,CLSIGNAL(INDMAX(ic)+1))
950
951 sr2 = 0 !right 2
952 if(
953 $ (ic.ne.NCLSTR1.and.(INDMAX(ic)+2).lt.INDSTART(ic+1))
954 $ .or.
955 $ (ic.eq.NCLSTR1.and.(INDMAX(ic)+2).le.TOTCLLENGTH)
956 $ )
957 $ sr2 = max(0.,CLSIGNAL(INDMAX(ic)+2))
958
959
960 if(mod(int(VIEW(ic)),2).eq.1)then !Y-view
961 f = 4.
962 si = 8.4
963 else !X-view
964 f = 6.
965 si = 3.9
966 endif
967
968 fbad_cog = 1.
969 f0 = 1
970 f1 = 1
971 f2 = 1
972 f3 = 1
973 if(sl1.gt.sr1.and.sl1.gt.0.)then
974
975 if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)) ).eq.0)f0=f
976 if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)-1)).eq.0)f1=f
977 c if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)+1)).eq.0)f3=f
978
979 if(ncog.eq.2.and.sl1.ne.0)then
980 fbad_cog = (f1**2*sc**2/sl1**2+f0**2)/(sc**2/sl1**2+1.)
981 elseif(ncog.eq.3.and.sl1.ne.0.and.sr1.ne.0)then
982 fbad_cog = 1.
983 elseif(ncog.eq.4.and.sl1.ne.0.and.sr1.ne.0.and.sl2.ne.0)then
984 fbad_cog = 1.
985 else
986 fbad_cog = 1.
987 endif
988
989 elseif(sl1.le.sr1.and.sr1.gt.0.)then
990
991
992 if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)) ).eq.0)f0=f
993 if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)+1)).eq.0)f1=f
994 c if(BAD(VIEW(ic),nvk(MAXS(ic)),nst(MAXS(ic)-1)).eq.0)f3=f
995
996 if(ncog.eq.2.and.sr1.ne.0)then
997 fbad_cog = (f1**2*sc**2/sr1**2+f0**2)/(sc**2/sr1**2+1.)
998 elseif(ncog.eq.3.and.sr1.ne.0.and.sl1.ne.0)then
999 fbad_cog = 1.
1000 elseif(ncog.eq.4.and.sr1.ne.0.and.sl1.ne.0.and.sr2.ne.0)then
1001 fbad_cog = 1.
1002 else
1003 fbad_cog = 1.
1004 endif
1005
1006 endif
1007
1008 fbad_cog0 = sqrt(fbad_cog)
1009
1010 return
1011 end
1012
1013
1014
1015
1016 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1017
1018 FUNCTION risx_eta2(x)
1019
1020 DOUBLE PRECISION V( 1)
1021 INTEGER NPAR, NDIM, IMQFUN, I, J
1022 DOUBLE PRECISION HQDJ, VV, VCONST
1023 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1024 DOUBLE PRECISION SIGV( 18, 1)
1025 DOUBLE PRECISION SIGDEL( 18)
1026 DOUBLE PRECISION SIGA( 18)
1027 DATA NPAR, NDIM, IMQFUN / 18, 1, 1/
1028 DATA VCONST / 0.000000000000 /
1029 DATA SIGVMI / -20.50000000000 /
1030 DATA SIGVT / 41.00000000000 /
1031 DATA SIGV / 0.6097560748458E-01
1032 +, 0.1097560971975
1033 +, 0.1341463327408
1034 +, 0.1829268187284
1035 +, 0.2317073047161
1036 +, 0.4268292486668
1037 +, 0.4756097495556
1038 +, 0.4999999701977
1039 +, 0.5243902206421
1040 +, 0.5731707215309
1041 +, 0.7682926654816
1042 +, 0.8170731663704
1043 +, 0.8658536076546
1044 +, 0.8902438879013
1045 +, 0.9390243291855
1046 +, 0.000000000000
1047 +, 1.000000000000
1048 +, 0.3658536374569
1049 +/
1050 DATA SIGDEL / 0.4878048598766E-01
1051 +, 0.4878048598766E-01
1052 +, 0.4878048598766E-01
1053 +, 0.4878048598766E-01
1054 +, 0.4878048598766E-01
1055 +, 0.4878048598766E-01
1056 +, 0.4878048598766E-01
1057 +, 0.4878048598766E-01
1058 +, 0.4878048598766E-01
1059 +, 0.4878048598766E-01
1060 +, 0.4878048598766E-01
1061 +, 0.4878048598766E-01
1062 +, 0.4878048598766E-01
1063 +, 0.4878048598766E-01
1064 +, 0.4878048598766E-01
1065 +, 0.1999999994950E-05
1066 +, 0.1999999994950E-05
1067 +, 0.9756097197533E-01
1068 +/
1069 DATA SIGA / 51.65899502118
1070 +, -150.4733247841
1071 +, 143.0468613786
1072 +, -16.56096738997
1073 +, 5.149319798083
1074 +, 21.57149712673
1075 +, -39.46652322782
1076 +, 47.13181632948
1077 +, -32.93197883680
1078 +, 16.38645317092
1079 +, 1.453688482992
1080 +, -10.00547244421
1081 +, 131.3517670587
1082 +, -140.6351538257
1083 +, 49.05515749582
1084 +, -23.00028974788
1085 +, -22.58470403729
1086 +, -3.824682486418
1087 +/
1088
1089 V(1)= abs(x)
1090
1091 HQUADF = 0.
1092 DO 20 J = 1, NPAR
1093 HQDJ = 0.
1094 DO 10 I = 1, NDIM
1095 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1096 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1097 10 CONTINUE
1098 HQDJ = HQDJ + SIGDEL (J) ** 2
1099 HQDJ = SQRT (HQDJ)
1100 HQUADF = HQUADF + SIGA (J) * HQDJ
1101 20 CONTINUE
1102 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1103
1104 risx_eta2=HQUADF* 1e-4
1105
1106 END
1107
1108 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1109 FUNCTION risx_eta3(x)
1110 DOUBLE PRECISION V( 1)
1111 INTEGER NPAR, NDIM, IMQFUN, I, J
1112 DOUBLE PRECISION HQDJ, VV, VCONST
1113 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1114 DOUBLE PRECISION SIGV( 18, 1)
1115 DOUBLE PRECISION SIGDEL( 18)
1116 DOUBLE PRECISION SIGA( 18)
1117 DATA NPAR, NDIM, IMQFUN / 18, 1, 1/
1118 DATA VCONST / 0.000000000000 /
1119 DATA SIGVMI / -20.50000000000 /
1120 DATA SIGVT / 41.00000000000 /
1121 DATA SIGV / 0.6097560748458E-01
1122 +, 0.1097560971975
1123 +, 0.1341463327408
1124 +, 0.1829268187284
1125 +, 0.2317073047161
1126 +, 0.4756097495556
1127 +, 0.4999999701977
1128 +, 0.5243902206421
1129 +, 0.7682926654816
1130 +, 0.8170731663704
1131 +, 0.8658536076546
1132 +, 0.8902438879013
1133 +, 0.9390243291855
1134 +, 0.000000000000
1135 +, 1.000000000000
1136 +, 0.3658536374569
1137 +, 0.4146341383457
1138 +, 0.6097560524940
1139 +/
1140 DATA SIGDEL / 0.4878048598766E-01
1141 +, 0.4878048598766E-01
1142 +, 0.4878048598766E-01
1143 +, 0.4878048598766E-01
1144 +, 0.4878048598766E-01
1145 +, 0.4878048598766E-01
1146 +, 0.4878048598766E-01
1147 +, 0.4878048598766E-01
1148 +, 0.4878048598766E-01
1149 +, 0.4878048598766E-01
1150 +, 0.4878048598766E-01
1151 +, 0.4878048598766E-01
1152 +, 0.4878048598766E-01
1153 +, 0.1999999994950E-05
1154 +, 0.1999999994950E-05
1155 +, 0.9756097197533E-01
1156 +, 0.9756097197533E-01
1157 +, 0.9756097197533E-01
1158 +/
1159 DATA SIGA / 55.18284054458
1160 +, -160.3358431242
1161 +, 144.6939185763
1162 +, -20.45200854118
1163 +, 5.223570087108
1164 +,-0.4171476953945
1165 +, -27.67911907462
1166 +, 17.70327157495
1167 +, -1.867165491707
1168 +, -8.884458169181
1169 +, 124.3526608791
1170 +, -143.3309398345
1171 +, 50.80345027122
1172 +, -16.44454904415
1173 +, -15.73785568450
1174 +, -22.71810502561
1175 +, 36.86170101430
1176 +, 2.437918198452
1177 +/
1178
1179 V(1) = abs(x)
1180 HQUADF = 0.
1181 DO 20 J = 1, NPAR
1182 HQDJ = 0.
1183 DO 10 I = 1, NDIM
1184 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1185 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1186 10 CONTINUE
1187 HQDJ = HQDJ + SIGDEL (J) ** 2
1188 HQDJ = SQRT (HQDJ)
1189 HQUADF = HQUADF + SIGA (J) * HQDJ
1190 20 CONTINUE
1191 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1192
1193 risx_eta3 = HQUADF* 1e-4
1194
1195 END
1196 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1197 FUNCTION risx_eta4(x)
1198 DOUBLE PRECISION V( 1)
1199 INTEGER NPAR, NDIM, IMQFUN, I, J
1200 DOUBLE PRECISION HQDJ, VV, VCONST
1201 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1202 DOUBLE PRECISION SIGV( 18, 1)
1203 DOUBLE PRECISION SIGDEL( 18)
1204 DOUBLE PRECISION SIGA( 18)
1205 DATA NPAR, NDIM, IMQFUN / 18, 1, 1/
1206 DATA VCONST / 0.000000000000 /
1207 DATA SIGVMI / -20.50000000000 /
1208 DATA SIGVT / 41.00000000000 /
1209 DATA SIGV / 0.3658536449075E-01
1210 +, 0.6097560748458E-01
1211 +, 0.1097560971975
1212 +, 0.1341463327408
1213 +, 0.4756097495556
1214 +, 0.5243902206421
1215 +, 0.8658536076546
1216 +, 0.8902438879013
1217 +, 0.9390243291855
1218 +, 0.9634146094322
1219 +, 0.000000000000
1220 +, 1.000000000000
1221 +, 0.3658536374569
1222 +, 0.4146341383457
1223 +, 0.6097560524940
1224 +, 0.6585365533829
1225 +, 0.7560975551605
1226 +, 0.2439024299383
1227 +/
1228 DATA SIGDEL / 0.4878048598766E-01
1229 +, 0.4878048598766E-01
1230 +, 0.4878048598766E-01
1231 +, 0.4878048598766E-01
1232 +, 0.4878048598766E-01
1233 +, 0.4878048598766E-01
1234 +, 0.4878048598766E-01
1235 +, 0.4878048598766E-01
1236 +, 0.4878048598766E-01
1237 +, 0.4878048598766E-01
1238 +, 0.1999999994950E-05
1239 +, 0.1999999994950E-05
1240 +, 0.9756097197533E-01
1241 +, 0.9756097197533E-01
1242 +, 0.9756097197533E-01
1243 +, 0.9756097197533E-01
1244 +, 0.9756097197533E-01
1245 +, 0.1951219439507
1246 +/
1247 DATA SIGA / -43.61551887895
1248 +, 57.88466995373
1249 +, -92.04113299504
1250 +, 74.08166649890
1251 +, -9.768686062558
1252 +, -4.304496875334
1253 +, 72.62237333937
1254 +, -91.21920840618
1255 +, 56.75519978630
1256 +, -43.21115751243
1257 +, 12.79984505413
1258 +, 12.10074868595
1259 +, -6.238587250860
1260 +, 23.43447356326
1261 +, 17.98221401495
1262 +, -7.980332610975
1263 +, -3.426733307051
1264 +, -8.683439558751
1265 +/
1266
1267 V(1)=abs(x)
1268
1269 HQUADF = 0.
1270 DO 20 J = 1, NPAR
1271 HQDJ = 0.
1272 DO 10 I = 1, NDIM
1273 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1274 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1275 10 CONTINUE
1276 HQDJ = HQDJ + SIGDEL (J) ** 2
1277 HQDJ = SQRT (HQDJ)
1278 HQUADF = HQUADF + SIGA (J) * HQDJ
1279 20 CONTINUE
1280 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1281
1282 risx_eta4=HQUADF* 1e-4
1283
1284 END
1285 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1286 FUNCTION risy_eta2(x)
1287 DOUBLE PRECISION V( 1)
1288 INTEGER NPAR, NDIM, IMQFUN, I, J
1289 DOUBLE PRECISION HQDJ, VV, VCONST
1290 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1291 DOUBLE PRECISION SIGV( 12, 1)
1292 DOUBLE PRECISION SIGDEL( 12)
1293 DOUBLE PRECISION SIGA( 12)
1294 DATA NPAR, NDIM, IMQFUN / 12, 1, 1/
1295 DATA VCONST / 0.000000000000 /
1296 DATA SIGVMI / -20.50000000000 /
1297 DATA SIGVT / 41.00000000000 /
1298 DATA SIGV / 0.1585365831852
1299 +, 0.4024389982224
1300 +, 0.4756097495556
1301 +, 0.5243902206421
1302 +, 0.5975609421730
1303 +, 0.8414633870125
1304 +, 0.000000000000
1305 +, 1.000000000000
1306 +, 0.2682926654816
1307 +, 0.3170731663704
1308 +, 0.7073170542717
1309 +, 0.7560975551605
1310 +/
1311 DATA SIGDEL / 0.4878048598766E-01
1312 +, 0.4878048598766E-01
1313 +, 0.4878048598766E-01
1314 +, 0.4878048598766E-01
1315 +, 0.4878048598766E-01
1316 +, 0.4878048598766E-01
1317 +, 0.1999999994950E-05
1318 +, 0.1999999994950E-05
1319 +, 0.9756097197533E-01
1320 +, 0.9756097197533E-01
1321 +, 0.9756097197533E-01
1322 +, 0.9756097197533E-01
1323 +/
1324 DATA SIGA / 14.57433603529
1325 +, -15.93532436156
1326 +, -13.24628335221
1327 +, -14.31193855410
1328 +, -12.67339684488
1329 +, 18.19876051780
1330 +, -5.270493486725
1331 +, -5.107670990828
1332 +, -9.553262933901
1333 +, 43.34150727448
1334 +, 55.91366786432
1335 +, -29.38037318563
1336 +/
1337
1338 v(1)= abs(x)
1339
1340 HQUADF = 0.
1341 DO 20 J = 1, NPAR
1342 HQDJ = 0.
1343 DO 10 I = 1, NDIM
1344 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1345 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1346 10 CONTINUE
1347 HQDJ = HQDJ + SIGDEL (J) ** 2
1348 HQDJ = SQRT (HQDJ)
1349 HQUADF = HQUADF + SIGA (J) * HQDJ
1350 20 CONTINUE
1351 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1352
1353 risy_eta2=HQUADF* 1e-4
1354
1355 END
1356 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1357
1358 FUNCTION risy_cog(x)
1359 DOUBLE PRECISION V( 1)
1360 INTEGER NPAR, NDIM, IMQFUN, I, J
1361 DOUBLE PRECISION HQDJ, VV, VCONST
1362 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1363 DOUBLE PRECISION SIGV( 10, 1)
1364 DOUBLE PRECISION SIGDEL( 10)
1365 DOUBLE PRECISION SIGA( 10)
1366 DATA NPAR, NDIM, IMQFUN / 10, 1, 1/
1367 DATA VCONST / 0.000000000000 /
1368 DATA SIGVMI / -20.50000000000 /
1369 DATA SIGVT / 41.00000000000 /
1370 DATA SIGV / 0.1585365831852
1371 +, 0.8414633870125
1372 +, 0.000000000000
1373 +, 1.000000000000
1374 +, 0.4634146094322
1375 +, 0.5121951103210
1376 +, 0.5609756112099
1377 +, 0.6585365533829
1378 +, 0.7073170542717
1379 +, 0.3414633870125
1380 +/
1381 DATA SIGDEL / 0.4878048598766E-01
1382 +, 0.4878048598766E-01
1383 +, 0.1999999994950E-05
1384 +, 0.1999999994950E-05
1385 +, 0.9756097197533E-01
1386 +, 0.9756097197533E-01
1387 +, 0.9756097197533E-01
1388 +, 0.9756097197533E-01
1389 +, 0.9756097197533E-01
1390 +, 0.1951219439507
1391 +/
1392 DATA SIGA / 23.73833445988
1393 +, 24.10182100013
1394 +, 1.865894323190
1395 +, 1.706006262931
1396 +, -1.075607857202
1397 +, -22.11489493403
1398 +, 1.663100707801
1399 +, 4.089852595440
1400 +, -4.314993873697
1401 +, -2.174479487744
1402 +/
1403
1404 V(1)=abs(x)
1405
1406 HQUADF = 0.
1407 DO 20 J = 1, NPAR
1408 HQDJ = 0.
1409 DO 10 I = 1, NDIM
1410 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1411 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1412 10 CONTINUE
1413 HQDJ = HQDJ + SIGDEL (J) ** 2
1414 HQDJ = SQRT (HQDJ)
1415 HQUADF = HQUADF + SIGA (J) * HQDJ
1416 20 CONTINUE
1417 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1418
1419 risy_cog=HQUADF* 1e-4
1420
1421 END
1422 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***
1423 FUNCTION risx_cog(x)
1424 DOUBLE PRECISION V( 1)
1425 INTEGER NPAR, NDIM, IMQFUN, I, J
1426 DOUBLE PRECISION HQDJ, VV, VCONST
1427 DOUBLE PRECISION SIGVMI( 1), SIGVT( 1)
1428 DOUBLE PRECISION SIGV( 15, 1)
1429 DOUBLE PRECISION SIGDEL( 15)
1430 DOUBLE PRECISION SIGA( 15)
1431 DATA NPAR, NDIM, IMQFUN / 15, 1, 1/
1432 DATA VCONST / 0.000000000000 /
1433 DATA SIGVMI / -20.50000000000 /
1434 DATA SIGVT / 41.00000000000 /
1435 DATA SIGV / 0.6097560748458E-01
1436 +, 0.8536584675312E-01
1437 +, 0.1341463327408
1438 +, 0.2317073047161
1439 +, 0.2804878056049
1440 +, 0.3780487775803
1441 +, 0.6219512224197
1442 +, 0.7195121645927
1443 +, 0.7682926654816
1444 +, 0.8658536076546
1445 +, 0.9146341085434
1446 +, 0.9390243291855
1447 +, 0.000000000000
1448 +, 1.000000000000
1449 +, 0.5121951103210
1450 +/
1451 DATA SIGDEL / 0.4878048598766E-01
1452 +, 0.4878048598766E-01
1453 +, 0.4878048598766E-01
1454 +, 0.4878048598766E-01
1455 +, 0.4878048598766E-01
1456 +, 0.4878048598766E-01
1457 +, 0.4878048598766E-01
1458 +, 0.4878048598766E-01
1459 +, 0.4878048598766E-01
1460 +, 0.4878048598766E-01
1461 +, 0.4878048598766E-01
1462 +, 0.4878048598766E-01
1463 +, 0.1999999994950E-05
1464 +, 0.1999999994950E-05
1465 +, 0.9756097197533E-01
1466 +/
1467 DATA SIGA / 31.95672945139
1468 +, -34.23286209245
1469 +, -6.298459168211
1470 +, 10.98847700545
1471 +,-0.3052213535054
1472 +, 13.10517991464
1473 +, 15.60290821679
1474 +, -1.956118448507
1475 +, 12.41453816720
1476 +, -7.354056408553
1477 +, -32.32512668778
1478 +, 30.61116178966
1479 +, 1.418505329236
1480 +, 1.583492573619
1481 +, -18.48799977042
1482 +/
1483
1484 V(1)=abs(x)
1485
1486 HQUADF = 0.
1487 DO 20 J = 1, NPAR
1488 HQDJ = 0.
1489 DO 10 I = 1, NDIM
1490 VV = (V (I) - SIGVMI (I)) / SIGVT (I)
1491 HQDJ = HQDJ + (VV - SIGV (J, I)) ** 2
1492 10 CONTINUE
1493 HQDJ = HQDJ + SIGDEL (J) ** 2
1494 HQDJ = SQRT (HQDJ)
1495 HQUADF = HQUADF + SIGA (J) * HQDJ
1496 20 CONTINUE
1497 IF (IMQFUN .EQ. 2) HQUADF = VCONST * EXP (HQUADF)
1498
1499 risx_cog = HQUADF * 1e-4
1500
1501 END
1502 *** * * * *** * * * *** * * * *** * * * *** * * * *** * * * ***

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