1 |
***************************************************************************** |
2 |
INTEGER FUNCTION CALOL2TR() |
3 |
c |
4 |
IMPLICIT NONE |
5 |
C |
6 |
INCLUDE 'INTEST.TXT' |
7 |
C |
8 |
DOUBLE PRECISION al_p(5), |
9 |
& xout(npla),yout(npla),zin(npla) |
10 |
C |
11 |
REAL PIANO(22), VARFIT(2) |
12 |
REAL TX, TY, SHIFT |
13 |
REAL BAR(2,NPLA), DISTY |
14 |
REAL DISTX, Y(NPLA), YY(NPLA) |
15 |
REAL RIG, PPLANEMAX, RMASS |
16 |
REAL RNSS, QTOTT, RQT, MX, MY |
17 |
REAL CHECK, ENER, CX, CY |
18 |
REAL EINF, ESUP, RPIANO(2) |
19 |
REAL hmemor(9000000), X01PL |
20 |
C |
21 |
REAL ax,bx,eax,ebx,chi2x |
22 |
REAL ay,by,eay,eby,chi2y |
23 |
REAL parzen3, TMISD |
24 |
INTEGER Nfitx,Nfity |
25 |
C |
26 |
INTEGER INDEX, NTOT(2), NPIANI, GTR |
27 |
INTEGER j, m, i, IWPL(2), timpx, timpy, T, nn |
28 |
INTEGER IPLANE, NNX, NNY, INFX, INFY, ISUPX, ISUPY |
29 |
INTEGER IBAR(2,NPLA), NPFIT(2), CHTRACK,IWPLU |
30 |
INTEGER Iquest(100), ICONTROL5, nin, IFAIL |
31 |
C |
32 |
PARAMETER (X01PL=0.74) |
33 |
C |
34 |
|
35 |
C |
36 |
COMMON / slftrig / tmisd,ax,bx,eax,ebx,chi2x,Nfitx,ay,by,eay,eby, |
37 |
& chi2y,Nfity,parzen3 |
38 |
SAVE / slftrig / |
39 |
C |
40 |
COMMON / TAGLIOEN / EINF, ESUP, ENER(2) |
41 |
SAVE / TAGLIOEN / |
42 |
C |
43 |
COMMON / SHIFT / SHIFT |
44 |
SAVE / SHIFT / |
45 |
C |
46 |
COMMON / ANGOLO / BAR, IBAR |
47 |
SAVE / ANGOLO / |
48 |
C |
49 |
COMMON / WHERE / CX, CY, PIANO |
50 |
SAVE / WHERE / |
51 |
C |
52 |
COMMON / GENERAL / RIG, RMASS |
53 |
SAVE / GENERAL / |
54 |
C |
55 |
COMMON / CH / CHECK |
56 |
SAVE / CH / |
57 |
C |
58 |
COMMON / CALOFIT / VARFIT, NPFIT |
59 |
SAVE / CALOFIT / |
60 |
C |
61 |
COMMON / pawcd / hmemor |
62 |
save / pawcd / |
63 |
C |
64 |
Common / QUESTd / Iquest |
65 |
save / questd / |
66 |
C |
67 |
C Begin ! |
68 |
C |
69 |
CALOL2TR = 0; |
70 |
NCORE = 0. |
71 |
QCORE = 0. |
72 |
NOINT = 0. |
73 |
QCYL = 0. |
74 |
NCYL = 0. |
75 |
QLOW = 0. |
76 |
NLOW = 0. |
77 |
QTR = 0. |
78 |
NTR = 0. |
79 |
QLAST = 0. |
80 |
QTRACK = 0. |
81 |
QPRESH = 0. |
82 |
NPRESH = 0. |
83 |
QTRACKX = 0. |
84 |
QTRACKY = 0. |
85 |
DXTRACK = 0. |
86 |
DYTRACK = 0. |
87 |
QPRE = 0. |
88 |
NPRE = 0. |
89 |
NLAST = 0. |
90 |
PLANETOT = 0. |
91 |
QMEAN = 0. |
92 |
SELFTRIGGER = 0 |
93 |
CALL VZERO(VARCFIT,2) |
94 |
CALL VZERO(NPCFIT,2) |
95 |
CALL VZERO(TBAR,2*NPLA) |
96 |
CALL VZERO(TIBAR,2*NPLA) |
97 |
CALL VZERO(BAR,2*NPLA) |
98 |
CALL VZERO(IBAR,2*NPLA) |
99 |
CALL VZERO(IBAR,2*NPLA) |
100 |
CALL VZERO(Y,NPLA) |
101 |
CALL VZERO(YY,NPLA) |
102 |
CALL VZERO(XOUT,NPLA) |
103 |
CALL VZERO(YOUT,NPLA) |
104 |
C |
105 |
C BEGIN WITH THE FISRT TRACK IF WE HAVE A TRACK FROM TRACKER |
106 |
C |
107 |
T = 1 |
108 |
C |
109 |
10 CONTINUE |
110 |
C |
111 |
IF (GOOD2.EQ.1) THEN |
112 |
C |
113 |
CHTRACK = 0 |
114 |
C |
115 |
CALL VZERO(IWPL,2) |
116 |
CALL VZERO(BAR,2*NPLA) |
117 |
CALL VZERO(IBAR,2*NPLA) |
118 |
CALL VZERO(TBAR,2*NPLA) |
119 |
CALL VZERO(TIBAR,2*NPLA) |
120 |
do m = 1, 5 |
121 |
al_p(m) = al_pp(t,m) |
122 |
enddo |
123 |
if (al_p(5).eq.0.) THEN |
124 |
PRINT *,' CALORIMETER - WARNING F77: track with R = 0, discarded' |
125 |
GOOD2 = 0 |
126 |
GOTO 969 |
127 |
ENDIF |
128 |
DO M = 1,2 |
129 |
DO I = 1,NPLA |
130 |
XOUT(I) = 0. |
131 |
YOUT(I) = 0. |
132 |
IF (MOD(M,2).EQ.0) THEN |
133 |
DISTX = PIANO(I) + ZALIG |
134 |
ELSE |
135 |
DISTX = PIANO(I) - 5.81 + ZALIG |
136 |
ENDIF |
137 |
ZIN(I) = distx / 10. |
138 |
TBAR(M,I) = 0. |
139 |
TIBAR(M,I) = 0 |
140 |
enddo |
141 |
IFAIL = 0 |
142 |
call DOTRACK(NPLA,ZIN,XOUT,YOUT,AL_P,IFAIL) |
143 |
if(IFAIL.ne.0)then |
144 |
GOOD2 = 0 |
145 |
c print *,' CALORIMETER - WARNING F77: tracking failed ' |
146 |
goto 969 |
147 |
endif |
148 |
TX = TAN(ASIN(AL_P(3))) * COS(AL_P(4)) |
149 |
TY = TAN(ASIN(AL_P(3))) * SIN(AL_P(4)) |
150 |
DO I = 1, NPLA |
151 |
NN = 0 |
152 |
IF (M.EQ.2) NN = 1 |
153 |
IF (MOD(I,2).EQ.NN) THEN |
154 |
SHIFT = +0.5 |
155 |
ELSE |
156 |
SHIFT = -0.5 |
157 |
ENDIF |
158 |
C |
159 |
C CHECK IF XOUT OR YOUT ARE NaN |
160 |
C |
161 |
IF (XOUT(I).NE.XOUT(I).OR.YOUT(I).NE.YOUT(I)) THEN |
162 |
c print *, |
163 |
c & ' CALORIMETER - WARNING F77: tracking error (NaN values)' |
164 |
GOOD2 = 0 |
165 |
GOTO 969 |
166 |
ENDIF |
167 |
C |
168 |
CX = XOUT(I)*10. + XALIG |
169 |
CY = YOUT(I)*10. + YALIG |
170 |
C |
171 |
IF (I.EQ.1) THEN |
172 |
TIMPX = CX |
173 |
TIMPY = CY |
174 |
ENDIF |
175 |
IF (M.EQ.1) THEN |
176 |
Y(I) = CX |
177 |
BAR(M,I) = Y(I) |
178 |
TBAR(M,I) = (Y(I) - XALIG)/10. |
179 |
IF (I.EQ.22) MX=ABS(Y(1)-Y(22))/ABS(ZIN(1)-ZIN(22)) |
180 |
ELSE |
181 |
YY(I) = CY |
182 |
BAR(M,I) = YY(I) |
183 |
TBAR(M,I) = (-YALIG + YY(I))/10. |
184 |
IF (I.EQ.22) MY=ABS(Y(1)-Y(22))/ABS(ZIN(1)-ZIN(22)) |
185 |
ENDIF |
186 |
CALL LASTRISCIA(BAR(M,I),IBAR(M,I)) |
187 |
tibar(M,I) = ibar(m,i) |
188 |
IF (ibar(m,i).EQ.-1) THEN |
189 |
CHTRACK = CHTRACK + 1 |
190 |
ELSE |
191 |
IWPL(M) = IWPL(M) + 1 |
192 |
ENDIF |
193 |
ENDDO |
194 |
ENDDO |
195 |
969 continue |
196 |
cC |
197 |
cC IF WE HAVE A GOOD CALORIMETER FIT DOES IT MATCH WITH TRACKER FIT? |
198 |
cC |
199 |
c IF (GOOD2.EQ.1.AND.NPFIT(2).GT.15.AND.VARFIT(2).LT.1000 |
200 |
c & .AND.TRKCHI2.EQ.1) THEN |
201 |
c IF (ABS(TBAR(2,1)-CBAR(2,1))<40.) THEN |
202 |
cC |
203 |
cC GOOD, THE TWO TRACKS COINCIDE |
204 |
cC |
205 |
c IF (T.EQ.2) TRKCHI2 = 2 |
206 |
c GOTO 6996 |
207 |
c ELSE |
208 |
cC |
209 |
cC IT IS NOT A GOOD FIT BUT WE HAVE AN IMAGE AND IT IS THE FIRST TRACK |
210 |
cC |
211 |
c IF (T.EQ.1) THEN |
212 |
c T = 2 |
213 |
c GOTO 10 |
214 |
c ENDIF |
215 |
c IF (T.EQ.2) THEN |
216 |
c TRKCHI2 = -1 |
217 |
c T = 1 |
218 |
c GOTO 10 |
219 |
c ENDIF |
220 |
c ENDIF |
221 |
c ENDIF |
222 |
C |
223 |
IF (GOOD2.EQ.0) THEN |
224 |
c IF (T.EQ.1.AND.TRKCHI2.EQ.1) THEN |
225 |
c GOOD2 = 1 |
226 |
c T = 2 |
227 |
c GOTO 10 |
228 |
c ENDIF |
229 |
GOTO 50 |
230 |
ENDIF |
231 |
C |
232 |
GOTO 6996 |
233 |
C |
234 |
ENDIF |
235 |
C |
236 |
C WE MUST PROCESS A SELFTRIGGER EVENT |
237 |
C |
238 |
IF (TRIGTY.GE.2) THEN |
239 |
C |
240 |
C CALL SELFTRIGGER SUBROUTINE |
241 |
C |
242 |
CALL SELFTRIG() |
243 |
ELEN = PARZEN3 |
244 |
SELEN = ABS(ELEN) * (11.98*1E-2 + 7.6 * EXP(-5736/ABS(ELEN))) |
245 |
C |
246 |
NPCFIT(1) = NFITX |
247 |
NPCFIT(2) = NFITY |
248 |
C |
249 |
DO M = 1,2 |
250 |
C |
251 |
IF (NPCFIT(M).GE.2) THEN |
252 |
IF (M.EQ.1) THEN |
253 |
VARCFIT(1) = CHI2X |
254 |
IMPX = 10. * ( AX + 12.1 ) |
255 |
TANX = BX |
256 |
ELSE |
257 |
VARCFIT(2) = CHI2Y |
258 |
IMPY = 10. * ( AY + 12.2 ) |
259 |
TANY = BY |
260 |
ENDIF |
261 |
C |
262 |
DO I = 1,NPLA |
263 |
NN = 0 |
264 |
IF (M.EQ.2) NN = 1 |
265 |
IF (MOD(I,2).EQ.NN) THEN |
266 |
SHIFT = +0.5 |
267 |
ELSE |
268 |
SHIFT = -0.5 |
269 |
ENDIF |
270 |
C |
271 |
IF (M.EQ.1) THEN |
272 |
DISTX = PIANO(I) - 5.81 |
273 |
Y(I) = DISTX * TANX + CX |
274 |
BAR(M,I) = Y(I) |
275 |
CBAR(M,I) = Y(I) |
276 |
IF (I.EQ.22) MX=ABS(Y(1)-Y(22))/ABS(ZIN(1)-ZIN(22)) |
277 |
C |
278 |
ELSE |
279 |
DISTY = PIANO(I) |
280 |
YY(I) = DISTY * TANY + CY |
281 |
BAR(M,I) = YY(I) |
282 |
CBAR(M,I) = YY(I) |
283 |
IF (I.EQ.22) MY=ABS(Y(1)-Y(22))/ABS(ZIN(1)-ZIN(22)) |
284 |
C |
285 |
ENDIF |
286 |
CALL LASTRISCIA(BAR(M,I),IBAR(M,I)) |
287 |
cibar(M,I) = ibar(m,i) |
288 |
ENDDO |
289 |
ENDIF |
290 |
C |
291 |
ENDDO |
292 |
C |
293 |
ELSE |
294 |
IF (GOOD2.EQ.0) THEN |
295 |
PRINT *,' CALORIMETER - WARNING F77: unknown request' |
296 |
GOOD2 = 1 |
297 |
GOTO 50 |
298 |
ENDIF |
299 |
ENDIF |
300 |
C |
301 |
6996 CONTINUE |
302 |
C |
303 |
DX0L = 0. |
304 |
C |
305 |
C IF THE TRACK IS OUTSIDE THE CALORIMETER GO OUT, IF NOT CALCULATE DX0L |
306 |
C |
307 |
IF (CHTRACK.EQ.44) THEN |
308 |
GOOD2 = 0 |
309 |
c PRINT *,' CALORIMETER - WARNING F77: track outside calorimeter' |
310 |
GOTO 50 |
311 |
ELSE |
312 |
IF ( IWPL(1).LE.IWPL(2) ) THEN |
313 |
IWPLU = IWPL(1) |
314 |
ELSE |
315 |
IWPLU = IWPL(2) |
316 |
ENDIF |
317 |
C |
318 |
DX0L = IWPLU * SQRT((BAR(2,1)-(2.66*MY+BAR(2,1)))**2 |
319 |
& + (BAR(1,1)-(2.66*MX+BAR(1,1)))**2 + 2.66**2) / |
320 |
& 3.6 |
321 |
C |
322 |
C DX0L = X01PL * SQRT( (IWPL(1) * SQRT(1 + MX*MX))**2 + |
323 |
C & (IWPL(2) * SQRT(1 + MY*MY))**2 )/2. |
324 |
ENDIF |
325 |
C |
326 |
C |
327 |
C RIG IS RIGIDITY AS DETERMINED BY THE TRACKER |
328 |
C OR by CALORIMETER IF IN SELFTRIGGER MODE |
329 |
C |
330 |
IF (GOOD2.EQ.1) THEN |
331 |
GTR = 1 |
332 |
IF (TRKCHI2.LT.0) GTR = 2 |
333 |
IF ( AL_PP(GTR,5).NE.0. ) THEN |
334 |
RIG = 1./(AL_PP(GTR,5)) |
335 |
ELSE |
336 |
GOOD2 = 0 |
337 |
PRINT *,' CALORIMETER - WARNING F77: track with R = 0' |
338 |
GOTO 50 |
339 |
ENDIF |
340 |
ENDIF |
341 |
IF (TRIGTY.GE.2.AND.GOOD2.EQ.0) THEN |
342 |
RIG = ELEN ! SELFTRIGGER RIGIDITY |
343 |
IF ( RIG.EQ.0. ) THEN |
344 |
GOOD2 = 0 |
345 |
PRINT *,' CALORIMETER - WARNING F77: ST track with R = 0' |
346 |
GOTO 50 |
347 |
ENDIF |
348 |
ENDIF |
349 |
C |
350 |
RNSS = 0. |
351 |
QTOTT = 0. |
352 |
C |
353 |
PPLANEMAX = 1.01*(LOG(ABS(RIG)/0.0081)-1.) |
354 |
C |
355 |
IPLANE = INT(ANINT(PPLANEMAX)) + 5 |
356 |
C |
357 |
IF (IPLANE.GT.NPLA) IPLANE=NPLA |
358 |
IF (IPLANE.LT.1) IPLANE = 1 |
359 |
C |
360 |
C CALCULATE QLOW AND NLOW |
361 |
C |
362 |
DO J = IPLANE,NPLA |
363 |
DO I = 1,NCHA |
364 |
IF (DEXY(1,J,I).GE.EMIN) THEN |
365 |
NLOW = NLOW + 1 |
366 |
QLOW = QLOW + DEXY(1,J,I) |
367 |
ENDIF |
368 |
IF (DEXY(2,J,I).GE.EMIN) THEN |
369 |
NLOW = NLOW + 1 |
370 |
QLOW = QLOW + DEXY(2,J,I) |
371 |
ENDIF |
372 |
ENDDO |
373 |
ENDDO |
374 |
C |
375 |
C CALCULATE QCORE AND NCORE |
376 |
C |
377 |
C |
378 |
C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm . |
379 |
C |
380 |
DO J = 1,IPLANE |
381 |
NNX = IBAR(1,J) |
382 |
IF (NNX.NE.-1) THEN |
383 |
IF (NNX.LT.9) NNX = 9 |
384 |
IF (NNX.GT.88) NNX = 88 |
385 |
INFX = NNX - 8 |
386 |
ISUPX = NNX + 8 |
387 |
DO I = INFX,ISUPX |
388 |
IF (DEXY(1,J,I).GE.EMIN) THEN |
389 |
RNSS = RNSS + 1 |
390 |
QTOTT = QTOTT + DEXY(1,J,I) |
391 |
ENDIF |
392 |
ENDDO |
393 |
ENDIF |
394 |
C |
395 |
NNY = IBAR(2,J) |
396 |
IF (NNY.NE.-1) THEN |
397 |
IF (NNY.LT.9) NNY = 9 |
398 |
IF (NNY.GT.88) NNY = 88 |
399 |
INFY = NNY - 8 |
400 |
ISUPY = NNY + 8 |
401 |
DO I = INFY,ISUPY |
402 |
IF (DEXY(2,J,I).GE.EMIN) THEN |
403 |
RNSS = RNSS + 1 |
404 |
QTOTT = QTOTT + DEXY(2,J,I) |
405 |
ENDIF |
406 |
ENDDO |
407 |
ENDIF |
408 |
NCORE = RNSS * FLOAT(J) + NCORE |
409 |
QCORE = QTOTT * FLOAT(J) + QCORE |
410 |
ENDDO |
411 |
C |
412 |
C CALCULATE NOINT |
413 |
C |
414 |
CALL NOINTER(NIN) |
415 |
NOINT = FLOAT(NIN) |
416 |
C |
417 |
C |
418 |
C QCYL = DETECTED ENERGY AND NCYL = NUMBER OF HIT STRIPS IN A CYLINDER oF |
419 |
C RADIUS 8.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING |
420 |
C PARTICLE . |
421 |
C |
422 |
C 8 STRIPS ARE 2.88 cm , A MOLIERE RADIUS IS ABOUT 0.7 cm . |
423 |
C |
424 |
DO J = 1,NPLA |
425 |
NNX = IBAR(1,J) |
426 |
IF (NNX.NE.-1) THEN |
427 |
IF (NNX.LT.9) NNX = 9 |
428 |
IF (NNX.GT.88) NNX = 88 |
429 |
INFX = NNX - 8 |
430 |
ISUPX = NNX + 8 |
431 |
DO I = INFX,ISUPX |
432 |
IF (DEXY(1,J,I).LT.EMIN) GO TO 710 |
433 |
NCYL = NCYL + 1 |
434 |
QCYL = QCYL + DEXY(1,J,I) |
435 |
710 ENDDO |
436 |
ENDIF |
437 |
NNY = IBAR(2,J) |
438 |
IF (NNY.NE.-1) THEN |
439 |
IF (NNY.LT.9) NNY = 9 |
440 |
IF (NNY.GT.88) NNY = 88 |
441 |
INFY = NNY - 8 |
442 |
ISUPY = NNY + 8 |
443 |
DO I=INFY,ISUPY |
444 |
IF (DEXY(2,J,I).LT.EMIN) GO TO 810 |
445 |
NCYL = NCYL + 1 |
446 |
QCYL = QCYL + DEXY(2,J,I) |
447 |
810 ENDDO |
448 |
ENDIF |
449 |
C |
450 |
C QTR = DETECTED ENERGY AND NTR = NUMBER OF HIT STRIPS IN A CYLINDER oF |
451 |
C RADIUS 4.5 STRIPS WITH AXIS DEFINED BY THE DIRECTION OF THE INCOMING |
452 |
C PARTICLE . |
453 |
C |
454 |
NNX = IBAR(1,J) |
455 |
IF (NNX.NE.-1) THEN |
456 |
IF (NNX.LT.5) NNX = 5 |
457 |
IF (NNX.GT.92) NNX = 92 |
458 |
INFX = NNX - 4 |
459 |
ISUPX = NNX + 4 |
460 |
DO I = INFX,ISUPX |
461 |
IF (DEXY(1,J,I).GT.EMIN) THEN |
462 |
NTR = NTR + 1 |
463 |
QTR = QTR + DEXY(1,J,I) |
464 |
ENDIF |
465 |
ENDDO |
466 |
ENDIF |
467 |
C |
468 |
NNY = IBAR(2,J) |
469 |
IF (NNY.NE.-1) THEN |
470 |
IF (NNY.LT.5) NNY = 5 |
471 |
IF (NNY.GT.92) NNY = 92 |
472 |
INFY = NNY - 4 |
473 |
ISUPY = NNY + 4 |
474 |
DO I = INFY, ISUPY |
475 |
IF (DEXY(2,J,I).GT.EMIN) THEN |
476 |
NTR = NTR + 1 |
477 |
QTR = QTR + DEXY(2,J,I) |
478 |
ENDIF |
479 |
ENDDO |
480 |
ENDIF |
481 |
ENDDO |
482 |
C |
483 |
C CALCULATE QTRACK |
484 |
C |
485 |
CALL LATERALE(QTRACK,RQT) |
486 |
|
487 |
C |
488 |
C CALCULATE NPRESH AND QPRESH |
489 |
C |
490 |
DO I = 1,4 |
491 |
NNX = IBAR(1,I) |
492 |
IF (NNX.NE.-1) THEN |
493 |
IF (NNX.LT.3) NNX = 3 |
494 |
IF (NNX.GT.94) NNX = 94 |
495 |
INFX = NNX - 2 |
496 |
ISUPX = NNX + 2 |
497 |
DO J = INFX,ISUPX |
498 |
IF (DEXY(1,I,J).GE.EMIN) THEN |
499 |
NPRESH = NPRESH + 1 |
500 |
QPRESH = QPRESH + DEXY(1,I,J) |
501 |
ENDIF |
502 |
ENDDO |
503 |
ENDIF |
504 |
C |
505 |
NNY = IBAR(2,I) |
506 |
IF (NNY.NE.-1) THEN |
507 |
IF (NNY.LT.3) NNY = 3 |
508 |
IF (NNY.GT.94) NNY = 94 |
509 |
INFY = NNY - 2 |
510 |
ISUPY = NNY + 2 |
511 |
DO J = INFY,ISUPY |
512 |
IF (DEXY(2,I,J).GE.EMIN) THEN |
513 |
NPRESH = NPRESH + 1 |
514 |
QPRESH = QPRESH + DEXY(2,I,J) |
515 |
ENDIF |
516 |
ENDDO |
517 |
ENDIF |
518 |
ENDDO |
519 |
C |
520 |
C CALCULATE DXTRACK, DYTRACK, QTRACKX AND QTRACKY |
521 |
C |
522 |
ICONTROL5 = 0 |
523 |
CALL NSHOWER(ICONTROL5,DXTRACK,DYTRACK,QTRACKX,QTRACKY) |
524 |
C |
525 |
C CALCULATE QPRE AND NPRE |
526 |
C |
527 |
DO J = 1,3 |
528 |
NNX = IBAR(1,J) |
529 |
IF (NNX.NE.-1) THEN |
530 |
IF (NNX.LT.9) NNX = 9 |
531 |
IF (NNX.GT.88) NNX = 88 |
532 |
INFX = NNX - 8 |
533 |
ISUPX = NNX + 8 |
534 |
DO I = INFX,ISUPX |
535 |
IF (DEXY(1,J,I).GE.EMIN) THEN |
536 |
NPRE = NPRE + 1 |
537 |
QPRE = QPRE + DEXY(1,J,I) |
538 |
ENDIF |
539 |
ENDDO |
540 |
ENDIF |
541 |
C |
542 |
NNY = IBAR(2,J) |
543 |
IF (NNY.NE.-1) THEN |
544 |
IF (NNY.LT.9) NNY = 9 |
545 |
IF (NNY.GT.88) NNY = 88 |
546 |
INFY = NNY - 8 |
547 |
ISUPY = NNY + 8 |
548 |
DO I=INFY,ISUPY |
549 |
IF (DEXY(2,J,I).GE.EMIN) THEN |
550 |
NPRE = NPRE + 1 |
551 |
QPRE = QPRE + DEXY(2,J,I) |
552 |
ENDIF |
553 |
ENDDO |
554 |
ENDIF |
555 |
ENDDO |
556 |
C |
557 |
C CALCULATE NLAST AND QLAST |
558 |
C |
559 |
DO J = NPLA-4,NPLA |
560 |
NNX = IBAR(1,J) |
561 |
IF (NNX.NE.-1) THEN |
562 |
IF (NNX.LT.5) NNX = 5 |
563 |
IF (NNX.GT.92) NNX = 92 |
564 |
c IF (NNX.LT.9) NNX = 9 |
565 |
c IF (NNX.GT.88) NNX = 88 |
566 |
INFX = NNX - 4 |
567 |
ISUPX = NNX + 4 |
568 |
c INFX = NNX - 8 |
569 |
c ISUPX = NNX + 8 |
570 |
DO I = INFX,ISUPX |
571 |
IF (DEXY(1,J,I).GE.EMIN) THEN |
572 |
NLAST = NLAST + 1 |
573 |
QLAST = QLAST + DEXY(1,J,I) |
574 |
ENDIF |
575 |
ENDDO |
576 |
ENDIF |
577 |
C |
578 |
NNY = IBAR(2,J) |
579 |
IF (NNY.NE.-1) THEN |
580 |
IF (NNY.LT.5) NNY = 5 |
581 |
IF (NNY.GT.92) NNY = 92 |
582 |
c IF (NNY.LT.9) NNY = 9 |
583 |
c IF (NNY.GT.88) NNY = 88 |
584 |
INFY = NNY - 4 |
585 |
ISUPY = NNY + 4 |
586 |
c INFY = NNY - 8 |
587 |
c ISUPY = NNY + 8 |
588 |
DO I=INFY,ISUPY |
589 |
IF (DEXY(2,J,I).GE.EMIN) THEN |
590 |
NLAST = NLAST + 1 |
591 |
QLAST = QLAST + DEXY(2,J,I) |
592 |
ENDIF |
593 |
ENDDO |
594 |
ENDIF |
595 |
ENDDO |
596 |
C |
597 |
EINF = EMIN |
598 |
ESUP = 50. |
599 |
C |
600 |
C CALCULATE PLANETOT AND QMEAN |
601 |
C |
602 |
DO M = 1,2 |
603 |
RPIANO(M) = 0. |
604 |
NTOT(M) = 0 |
605 |
ENDDO |
606 |
NPIANI = 5 |
607 |
QMEAN = 0. |
608 |
INDEX = 0 |
609 |
CALL ELIO(RPIANO,NPIANI,QMEAN,NTOT,INDEX) |
610 |
PLANETOT = RPIANO(1) + RPIANO(2) |
611 |
C |
612 |
50 CONTINUE |
613 |
C |
614 |
RETURN |
615 |
END |
616 |
|
617 |
|