source: trunk/MagicSoft/Simulation/Corsika/Mmcs/update.f@ 6724

Last change on this file since 6724 was 286, checked in by harald, 25 years ago
This is the start point for further developments of the Magic Monte Carlo Simulation written by Jose Carlos Gonzales. Now it is under control of one CVS repository for the whole collaboration. Everyone should use this CVS repository for further developments.
File size: 16.4 KB
Line 
1 SUBROUTINE UPDATE( HNEW,THCKHN,IPAS )
2
3C-----------------------------------------------------------------------
4C UPDATE(S PARTICLE PARAMETERS)
5C
6C UPDATES PARTICLE PARAMETERS TO OBSERVATION LEVEL WITH NUMBER IPAS
7C OR TO POINT OF INTERACTION OR DECAY (IPAS=0)
8C FOR CHARGED PARTICLES THE ENERGY LOSS IS COMPUTED FOR THE WHOLE STEP,
9C SUBDIVIDED BY THE BOUNDARIES OF THE ATMOSPHERIC LAYERS.
10C THE PARTICLE IS FLYING THE 1ST HALF (DH/2) WITH INITIAL ENERGY
11C AND ANGLE AND THE 2ND HALF WITH FINAL ENERGY AND ANGLE.
12C THE TIME CALCULATION FOLLOWS THIS SIMPLIFICATION.
13C CHARGED PARTICLES ARE DEFLECTED IN THE EARTH MAGNETIC FIELD.
14C THE ANGLE OF DEFLECTION BY MULTIPLE SCATTERING IS COMPUTED ONLY
15C FOR MUONS AND ONLY ONCE FOR THE WHOLE STEP.
16C IF PARTICLES COME TO REST BY STOPPING, THEIR PATH TO THE STOPPING
17C POINT IS CALCULATED.
18C CERENKOV RADIATION IS CALCULATED ONLY FOR LOWEST OBSERVATION LEVEL
19C THIS SUBROUTINE IS CALLED FROM MAIN, BOX3, AND MUTRAC
20C ARGUMENTS:
21C HNEW = ALTITUDE OF PARTICLE AFTER UPDATE
22C THCKHN = THICKNESS OF HNEW
23C IPAS = 0 TRANSPORT TO END OF RANGE OF PARTICLE
24C .NE. 0 TRANSPORT TO PASSAGE OF OBSERVATION LEVEL IPAS
25C
26C REDESIGN: D. HECK IK3 FZK KARLSRUHE
27C-----------------------------------------------------------------------
28
29 IMPLICIT NONE
30*KEEP,ATMOS2.
31 COMMON /ATMOS2/ HLAY,THICKL
32 DOUBLE PRECISION HLAY(5),THICKL(5)
33*KEEP,CONST.
34 COMMON /CONST/ PI,PI2,OB3,TB3,ENEPER
35 DOUBLE PRECISION PI,PI2,OB3,TB3,ENEPER
36*KEEP,ELABCT.
37 COMMON /ELABCT/ ELCUT
38 DOUBLE PRECISION ELCUT(4)
39*KEEP,GENER.
40 COMMON /GENER/ GEN,ALEVEL
41 DOUBLE PRECISION GEN,ALEVEL
42*KEEP,IRET.
43 COMMON /IRET/ IRET1,IRET2
44 INTEGER IRET1,IRET2
45*KEEP,MAGNET.
46 COMMON /MAGNET/ BX,BZ,BVAL,BNORMC,BNORM,COSB,SINB,BLIMIT
47 DOUBLE PRECISION BX,BZ,BVAL,BNORMC
48 REAL BNORM,COSB,SINB,BLIMIT
49*KEEP,MUMULT.
50 COMMON /MUMULT/ CHC,OMC,FMOLI
51 DOUBLE PRECISION CHC,OMC
52 LOGICAL FMOLI
53*KEEP,OBSPAR.
54 COMMON /OBSPAR/ OBSLEV,THCKOB,XOFF,YOFF,THETAP,PHIP,
55 * THETPR,PHIPR,NOBSLV
56 DOUBLE PRECISION OBSLEV(10),THCKOB(10),XOFF(10),YOFF(10),
57 * THETAP,THETPR(2),PHIP,PHIPR(2)
58 INTEGER NOBSLV
59*KEEP,PAM.
60 COMMON /PAM/ PAMA,SIGNUM
61 DOUBLE PRECISION PAMA(6000),SIGNUM(6000)
62*KEEP,PARPAR.
63 COMMON /PARPAR/ CURPAR,SECPAR,PRMPAR,OUTPAR,C,
64 * E00,E00PN,PTOT0,PTOT0N,THICKH,ITYPE,LEVL
65 DOUBLE PRECISION CURPAR(14),SECPAR(14),PRMPAR(14),OUTPAR(14),
66 * C(50),E00,E00PN,PTOT0,PTOT0N,THICKH
67 INTEGER ITYPE,LEVL
68*KEEP,PARPAE.
69 DOUBLE PRECISION GAMMA,COSTHE,PHI,H,T,X,Y,CHI,BETA,GCM,ECM
70 EQUIVALENCE (CURPAR(2),GAMMA), (CURPAR(3),COSTHE),
71 * (CURPAR(4), PHI ), (CURPAR(5), H ),
72 * (CURPAR(6), T ), (CURPAR(7), X ),
73 * (CURPAR(8), Y ), (CURPAR(9), CHI ),
74 * (CURPAR(10),BETA), (CURPAR(11),GCM ),
75 * (CURPAR(12),ECM )
76*KEEP,RANDPA.
77 COMMON /RANDPA/ FAC,U1,U2,RD,NSEQ,ISEED,KNOR
78 DOUBLE PRECISION FAC,U1,U2
79 REAL RD(3000)
80 INTEGER ISEED(103,10),NSEQ
81 LOGICAL KNOR
82*KEEP,RUNPAR.
83 COMMON /RUNPAR/ FIXHEI,THICK0,HILOECM,HILOELB,
84 * STEPFC,NRRUN,NSHOW,PATAPE,MONIIN,
85 * MONIOU,MDEBUG,NUCNUC,
86 * CETAPE,
87 * SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
88 * N1STTR,MDBASE,
89 * DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
90 * FIX1I,FMUADD,FNKG,FPRINT,FDBASE
91 * ,GHEISH,GHESIG
92 COMMON /RUNPAC/ DSN,HOST,USER
93 DOUBLE PRECISION FIXHEI,THICK0,HILOECM,HILOELB
94 REAL STEPFC
95 INTEGER NRRUN,NSHOW,PATAPE,MONIIN,MONIOU,MDEBUG,NUCNUC,
96 * SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
97 * N1STTR,MDBASE
98 INTEGER CETAPE
99 CHARACTER*79 DSN
100 CHARACTER*20 HOST,USER
101
102 LOGICAL DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
103 * FIX1I,FMUADD,FNKG,FPRINT,FDBASE
104 * ,GHEISH,GHESIG
105*KEEP,CERHDR.
106 COMMON/CERHDR/ TPART,UPART,VPART,WPART,XPART,YPART,ZPART
107 DOUBLE PRECISION TPART,UPART,VPART,WPART,XPART,YPART,ZPART
108*KEND.
109
110 DOUBLE PRECISION ALPHA1,ALPHA2,BETAN,DENS,DH,DR,DTHICK,ELOSS,
111 * FNORM1,FNORM2,F1COS1,F1COS2,F1SIN1,F1SIN2,
112 * GAMMAN,GAMSQ,GLCUT,GMSQM1,GAM0,HMIDDL,HNEW,OMEGA,
113 * PHISCT,PHI1,RADINV,RANNOR,RHOF,
114 * SINTH1,SINTH2,SN,SN1,SN2,SN3,SN4,
115 * THCKHN,TH0,U10,U12,U20,U22,V,VSCAT,VVV,
116 * V10,V12,V20,V22,W10,W12,W20,W22
117 INTEGER I,IL,ILAY,IPAS
118 LOGICAL MUS
119 SAVE VSCAT,PHISCT
120 EXTERNAL RANNOR,RHOF
121 DOUBLE PRECISION CHIT,DT,GAMK,HEIGH,HNEWC,RATIO,THCKHC
122 INTEGER ICRNKV
123 LOGICAL TFLAG
124 EXTERNAL HEIGH
125C-----------------------------------------------------------------------
126
127 IF (DEBUG) WRITE(MDEBUG,457) (CURPAR(I),I=1,9),HNEW
128 457 FORMAT(' UPDATE: CURPAR=',1P,9E10.3/
129 * ' TO HEIGHT ',0P,F11.1)
130
131 IRET2 = 1
132C TOTAL HEIGHT DIFFERENCE
133 DH = MAX( H - HNEW, 1.D-10 )
134C ATMOSPHERE THICKNESS TRAVERSED
135 DTHICK = (THCKHN - THICKH) / COSTHE
136C TOTAL PATH FOR UNDEFLECTED PARTICLE
137 SN = DH / COSTHE
138 SN1 = 0.25D0 * SN
139
140
141C CALCULATE KINETIC ENERGY CUT
142 IF ( ITYPE .EQ. 5 .OR. ITYPE .EQ. 6 ) THEN
143 MUS = .TRUE.
144 GLCUT = ELCUT(2) / PAMA(ITYPE) + 1.D0
145 ELSE
146 MUS = .FALSE.
147 GLCUT = ELCUT(1) / PAMA(ITYPE) + 1.D0
148 ENDIF
149
150C CALCULATE THE ENERGY LOSS FOR CHARGED PARTICLES
151 IF ( SIGNUM(ITYPE) .NE. 0.D0 ) THEN
152C LOOK WITHIN WHICH LAYER THE PARTICLE STARTS
153 IF ( H .LE. HLAY(2) ) THEN
154 ILAY = 1
155 TH0 = THICKH
156 ELSEIF ( H .LE. HLAY(3) ) THEN
157 ILAY = 2
158 TH0 = THICKH
159 ELSEIF ( H .LE. HLAY(4) ) THEN
160 ILAY = 3
161 TH0 = THICKH
162 ELSE
163 ILAY = 4
164 TH0 = MAX( THICKH, 2.D-4 )
165 ENDIF
166C SET START VALUES FOR ITERATION
167 GAM0 = GAMMA
168 IL = ILAY
169 1 CONTINUE
170 GAM0 = MAX( GAM0, 1.0001D0 )
171 GAMSQ = GAM0**2
172 GMSQM1 = GAMSQ - 1.D0
173C ENERGY LOSS BY IONIZATION
174 ELOSS = SIGNUM(ITYPE)**2 * C(22) *
175 * ( GAMSQ * (LOG(GMSQM1) + C(23)) / GMSQM1 - 1.D0 )
176C LOOK WETHER PARTICLE PENETRATES LAYER BOUNDARY
177 IF ( THICKL(IL) .LT. THCKHN .AND. IL .GT. 1 ) THEN
178C CALCULATE NEW START VALUES AT LAYER BOUNDARY
179 GAM0 = GAM0 - ELOSS * (THICKL(IL) - TH0)
180 * / (PAMA(ITYPE)*COSTHE)
181 IF ( GAM0 .LE. 1.D0 ) THEN
182 GAMMAN = 1.0001D0
183 GOTO 3
184 ENDIF
185 TH0 = THICKL(IL)
186 IL = IL - 1
187 GOTO 1
188 ENDIF
189C GAMMA VALUE FOR CHARGED PARTICLES AT END OF STEP
190 GAMMAN = GAM0 - ELOSS * (THCKHN-TH0) / (PAMA(ITYPE)*COSTHE)
191 3 CONTINUE
192
193 ELSE
194C NO LOSS FOR NEUTRAL PARTICLES
195 GAMMAN = GAMMA
196 ENDIF
197
198C PARTICLE HAS TO BE TRACKED TO THE CUTOFF ENERGY FOR CERENKOV PHOTONS
199C (AS NEUTRAL DO NOT LOOSE ENERGY IN UPDATE, THIS CONDITION IS
200C FULFILLED BY CHARGED PARTICLES ONLY)
201C (AS CERENKOV RUNS NOT WITH HORIZONT, NO PROGRAMMING FOR HORIZONT)
202 IF ( GAMMAN .LT. GLCUT ) THEN
203 GAMMAN = 0.9D0 + GLCUT * 0.1D0
204
205C SET START VALUES FOR ITERATION
206 IL = ILAY
207 CHIT = 0.D0
208 GAM0 = GAMMA
209 TH0 = MAX( THICKH, 2.D-4 )
210 2 CONTINUE
211 GAM0 = MAX( GAM0, 1.0001D0 )
212 GAMSQ = GAM0**2
213 GMSQM1 = GAMSQ - 1.D0
214C ENERGY LOSS BY IONIZATION
215 ELOSS = SIGNUM(ITYPE)**2 * C(22) *
216 * ( GAMSQ * (LOG(GMSQM1) + C(23)) / GMSQM1 -1.D0 )
217 ELOSS = ELOSS / (PAMA(ITYPE) * COSTHE)
218 GAMK = GAM0 - ELOSS * (THICKL(ILAY) - TH0)
219C LOOK WETHER PARTICLE PENETRATES LAYER BOUNDARY
220 IF (GAMMAN .LT. GAMK .AND. IL. GT. 1 ) THEN
221C CALCULATE PORTION OF RANGE AND NEW START VALUES AT LAYER BOUNDARY
222 CHIT = CHIT + (THICKL(IL) - TH0) / COSTHE
223 GAM0 = GAMK
224 TH0 = THICKL(IL)
225 IL = IL - 1
226 GOTO 2
227 ENDIF
228C PENETRATED MATTER THICKNESS
229 CHI = CHIT + (GAM0 - GAMMAN) / (ELOSS*COSTHE)
230 IF ( DEBUG ) WRITE(MDEBUG,*)'UPDATE: GAMMAN,CHI=',
231 * SNGL(GAMMAN),SNGL(CHI)
232C CALCULATE CORRECTED PATH PARAMETERS
233 THCKHC = THICKH + COSTHE * CHI
234 HNEWC = HEIGH(THCKHC)
235 DT = SN / (C(25) * BETA * GAMMA)
236 RATIO = .5D0 * (H-HNEWC) / DH
237 DH = H - HNEWC
238 SN = DH / COSTHE
239 SN1 = 0.25D0 * SN
240 TFLAG = .TRUE.
241 ELSE
242 TFLAG = .FALSE.
243 ENDIF
244
245C-----------------------------------------------------------------------
246 IF ( IPAS .EQ. 0 ) THEN
247C UPDATE TO THE END POINT OF THE TRACK
248
249 IF ( MUS ) THEN
250C COULOMB SCATTERING ANGLE (FOR MUONS ONLY)
251 IF ( FMOLI) THEN
252C TREAT MUON MULTIPLE SCATTERING BY MOLIERE THEORY (SEE GEANT)
253C CALCULATE AVERAGE DENSITY AND NUMBER OF SCATTERING (OMEGA)
254 DENS = CHI/DH * COSTHE
255 OMEGA = OMC * CHI / BETA**2
256 IF ( OMEGA .LE. 20.D0 ) THEN
257C FEW SCATTERING EVENTS, APPLY PLURAL COULOMB SCATTERING
258 CALL MUCOUL(OMEGA,DENS,VSCAT)
259 ELSE
260C ENOUGH SCATTERING EVENTS, APPLY MOLIERE'S THEORY
261 CALL MMOLIE(OMEGA,DENS,VSCAT)
262 ENDIF
263 ELSE
264C TREAT MUON MULTIPLE SCATTERING BY GAUSS DISTRIBUTION
265 VSCAT = RANNOR( 0.D0, C(30) * SQRT( CHI/C(21) )
266 * / (PAMA(5) * GAMMA * BETA**2) )
267 ENDIF
268 V = VSCAT
269 CALL RMMAR( RD,1,1 )
270 PHISCT = RD(1) * PI2
271 IF(DEBUG)WRITE(MDEBUG,*)'UPDATE: VSCAT=',SNGL(VSCAT),
272 * ' PHISCT=',SNGL(PHISCT)
273 ENDIF
274
275C CERENKOV RADIATION: LOOK, WHETHER PATH ENDS ABOVE LOWEST OBSERV.LEVEL
276 IF ( TFLAG ) THEN
277 HNEW = HNEWC
278 THCKHN = THCKHC
279 IF (DEBUG) WRITE(MDEBUG,*)'UPDATE: CHANGED HNEW =',SNGL(HNEW)
280 ENDIF
281 IF ( HNEW .GT. OBSLEV(NOBSLV) ) THEN
282 ICRNKV = 1
283 ELSE
284 ICRNKV = 0
285 ENDIF
286
287C UPDATE TO THE OBSERVATION LEVELS
288 ELSE
289 IF ( MUS ) THEN
290C COULOMB SCATTERING ANGLE (FOR MUONS ONLY)
291 V = VSCAT * SQRT( DTHICK / CHI )
292 ENDIF
293
294C CERENKOV RADIATION: LOOK, WHETHER LOWEST OBSERVATION LEVEL
295 IF ( IPAS .EQ. NOBSLV ) THEN
296 ICRNKV = 1
297 ELSE
298 ICRNKV = 0
299 ENDIF
300 ENDIF
301
302C REJECT ALL PARTICLES IF BELOW KINETIC ENERGY CUT
303 IF ( GAMMAN .LT. GLCUT .AND. ICRNKV .EQ. 0 ) THEN
304 IF (DEBUG)
305 * WRITE(MDEBUG,*) 'UPDATE: PARTICLE ',ITYPE,' BELOW ENERGY CUT'
306 * ,' CERENKOV LIGHT NOT CALCULATED'
307 RETURN
308 ENDIF
309
310C-----------------------------------------------------------------------
311C CHARGED PARTICLES SUFFER IONIZATION LOSS, DEFLECTION IN MAGNETIC
312C FIELD AND MUONS IN ADDITION DO MULTIPLE COULOMB SCATTERING
313
314 IF ( SIGNUM(ITYPE) .NE. 0.D0 ) THEN
315C DEFLECTION IN EARTH MAGNETIC FIELD ON FIRST HALF OF STEP
316 ALPHA1 = SIGNUM(ITYPE) *
317 * MIN( 1.D0, 2.D0*SN1*BNORMC /(PAMA(ITYPE)*BETA*GAMMA) )
318 SINTH1 = SQRT( 1.D0 - COSTHE**2 )
319 U10 = SINTH1 * COS(-PHI)
320 V10 = SINTH1 * SIN(-PHI)
321 W10 = COSTHE
322 FNORM1 = 1.D0 - 0.5D0*ALPHA1**2 * (1.D0 - 0.75D0*ALPHA1**2)
323 F1COS1 = ( 1.D0 - FNORM1 ) * COSB
324 F1SIN1 = ( 1.D0 - FNORM1 ) * SINB
325 VVV = V10 * ALPHA1 * FNORM1
326 U12 = U10 * (1.D0 - F1SIN1*SINB) + W10*F1SIN1*COSB + VVV*SINB
327 V12 = FNORM1 * ( V10 - ALPHA1 * (U10 * SINB - W10 * COSB) )
328 W12 = W10 * (1.D0 - F1COS1*COSB) + U10*F1COS1*SINB - VVV*COSB
329 RADINV = 1.5D0 - 0.5D0 * ( U12**2 + V12**2 + W12**2 )
330 W12 = MIN( 1.D0, RADINV * W12 )
331 IF ( W12 .LE. C(29) ) THEN
332 IF (DEBUG)
333 * WRITE(MDEBUG,*) 'UPDATE: PARTICLE ',ITYPE,' BELOW ANGLE CUT 1'
334 RETURN
335 ENDIF
336 SN2 = 0.25D0 * DH / W12
337 U12 = RADINV * U12
338 V12 = RADINV * V12
339 IF ( U12**2 + V12**2 .GT. 3.D-38 ) THEN
340 PHI1 = -ATAN2( V12, U12 )
341 ELSE
342 PHI1 = 0.D0
343 ENDIF
344C CERENKOV RADIATION: FILL PARTICLE COORDINATES INTO COMMON CERHDR
345 IF ( ICRNKV .EQ. 1 ) THEN
346 XPART = X + SN1 * U10 + SN2 * U12
347 YPART = Y - SN1 * V10 - SN2 * V12
348 TPART = T + ( SN1 + SN2 ) / ( C(25) * BETA )
349 ZPART = H - DH * 0.5D0
350 WPART = W12
351 UPART = U12
352 VPART = -V12
353 CALL CERENH( SN1+SN2, BETA )
354 ENDIF
355
356C CHANGE DIRECTION BY COULOMB SCATTERING (FOR MUONS ONLY)
357C BEFORE SCATTERING : DIRECTION COSINES ARE U12,V12,W12
358C AFTER SCATTERING : DIRECTION COSINES ARE U20,V20,W20
359 IF ( MUS ) THEN
360 CALL ADDANG( W12,PHI1, COS(V),PHISCT, W20,PHI1 )
361 IF ( W20 .LT. C(29) ) THEN
362 IF (DEBUG) WRITE(MDEBUG,*) 'UPDATE: MUON BELOW ANGLE CUT'
363 RETURN
364 ENDIF
365 SINTH2 = SQRT( 1.D0 - W20**2 )
366 U20 = SINTH2 * COS( -PHI1 )
367 V20 = SINTH2 * SIN( -PHI1 )
368 ELSE
369 U20 = U12
370 V20 = V12
371 W20 = W12
372 ENDIF
373
374C NEW PATH LENGTH, NEW BETA VALUE BECAUSE OF IONIZATION ENERGY LOSS
375 SN3 = 0.25D0 * DH / W20
376 BETAN = SQRT( GAMMAN**2 - 1.D0 ) / GAMMAN
377C DEFLECTION IN EARTH MAGNETIC FIELD ON SECOND HALF OF STEP
378 ALPHA2 = SIGNUM(ITYPE) *
379 * MIN(1.D0,2.D0*SN3*BNORMC / (PAMA(ITYPE)*BETAN*GAMMAN))
380 FNORM2 = 1.D0 - 0.5D0*ALPHA2**2 * (1.D0 - 0.75D0*ALPHA2**2)
381 F1SIN2 = ( 1.D0 - FNORM2 ) * SINB
382 F1COS2 = ( 1.D0 - FNORM2 ) * COSB
383 VVV = V20 * ALPHA2 * FNORM2
384 U22 = U20*(1.D0 - F1SIN2*SINB) + W20*F1SIN2*COSB + VVV*SINB
385 V22 = FNORM2 * ( V20 - ALPHA2 * (U20 * SINB - W20 * COSB) )
386 W22 = W20*(1.D0 - F1COS2*COSB) + U20*F1COS2*SINB - VVV*COSB
387 RADINV = 1.5D0 - 0.5D0 * ( U22**2 + V22**2 + W22**2 )
388 W22 = MIN( 1.D0, RADINV * W22 )
389 IF ( W22 .LT. C(29) ) THEN
390 IF (DEBUG)
391 * WRITE(MDEBUG,*) 'UPDATE: PARTICLE ',ITYPE,' BELOW ANGLE CUT 2'
392 RETURN
393 ENDIF
394 SN4 = 0.25D0 * DH / W22
395 U22 = RADINV * U22
396 V22 = RADINV * V22
397 OUTPAR(3) = W22
398 IF ( U22**2 + V22**2 .GT. 3.D-38 ) THEN
399 OUTPAR(4) = -ATAN2( V22, U22 )
400 ELSE
401 OUTPAR(4) = 0.D0
402 ENDIF
403C UPDATE COORDINATES AND TIME TO THE END OF DISTANCE
404 IF ( TFLAG ) THEN
405 OUTPAR(6) = T + DT* ( RATIO*GAMMA + (1.D0-RATIO)*GAMMAN)
406 ELSE
407 OUTPAR(6) = T + (SN1 + SN2)/(BETA *C(25)) +
408 * (SN3 + SN4)/(BETAN*C(25))
409 ENDIF
410 OUTPAR(7) = X + SN1*U10 + SN2*U12 + SN3*U20 + SN4*U22
411 OUTPAR(8) = Y - SN1*V10 - SN2*V12 - SN3*V20 - SN4*V22
412C CERENKOV RADIATION: FILL PARTICLE COORDINATES INTO COMMON CERHDR
413 IF ( ICRNKV .EQ. 1 ) THEN
414 XPART = OUTPAR(7)
415 YPART = OUTPAR(8)
416 ZPART = HNEW
417 TPART = OUTPAR(6)
418 WPART = W22
419 UPART = U22
420 VPART = -V22
421 CALL CERENH( SN3+SN4, BETAN )
422C REJECT PARTICLES AFTER PRODUCTION OF CERENKOV LIGHT
423 IF ( GAMMAN .LT. GLCUT ) THEN
424 IF (DEBUG) WRITE(MDEBUG,*) 'UPDATE: PARTICLE ',ITYPE,
425 * ' BELOW ENERGY CUT AFTER CREATION OF CERENKOV LIGHT'
426 RETURN
427 ENDIF
428 ENDIF
429 ELSE
430
431C-----------------------------------------------------------------------
432C NEUTRAL PARTICLES
433C NO COULOMB SCATTERING, NO DEFLECTION IN MAGNETIC FIELD
434
435C HORIZONTAL PATH LENGTH
436 DR = SN * SQRT( 1.D0 - COSTHE**2 )
437C UPDATE COORDINATES AND TIME
438 OUTPAR(3) = COSTHE
439 OUTPAR(4) = PHI
440 OUTPAR(6) = T + SN / ( C(25) * BETA )
441 OUTPAR(7) = X + DR * COS(PHI)
442 OUTPAR(8) = Y + DR * SIN(PHI)
443 ENDIF
444
445C-----------------------------------------------------------------------
446 OUTPAR( 1) = CURPAR(1)
447 OUTPAR( 2) = GAMMAN
448 OUTPAR( 5) = HNEW
449 OUTPAR( 9) = GEN
450 OUTPAR(10) = ALEVEL
451
452C REGULAR END OF UPDATE
453 IRET2 = 0
454
455
456 IF (DEBUG) WRITE(MDEBUG,458) (OUTPAR(I),I=1,9)
457 458 FORMAT(' UPDATE: OUTPAR=',1P,9E10.3)
458
459 RETURN
460 END
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