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hdpm.f@ 4308

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Last change on this file since 4308 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: 32.5 KB

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1	SUBROUTINE HDPM
2
3	C-----------------------------------------------------------------------
4	C H(ADRONIC) D(UAL) P(ARTON) M(ODEL)
5	C
6	C GENERATOR OF HADRONIC COLLISION INSPIRED BY DUAL PARTON MODEL
7	C THIS SUBROUTINE IS CALLED FROM SDPM
8	C-----------------------------------------------------------------------
9
10	IMPLICIT DOUBLE PRECISION (A-H,O-Z)
11	*KEEP,CONST.
12	COMMON /CONST/ PI,PI2,OB3,TB3,ENEPER
13	DOUBLE PRECISION PI,PI2,OB3,TB3,ENEPER
14	*KEEP,DPMFLG.
15	COMMON /DPMFLG/ NFLAIN,NFLDIF,NFLPI0,NFLCHE,NFLPIF,NFRAGM
16	INTEGER NFLAIN,NFLDIF,NFLPI0,NFLCHE,NFLPIF,NFRAGM
17	*KEEP,ELADPM.
18	COMMON /ELADPM/ ELMEAN,ELMEAA,IELDPM,IELDPA
19	DOUBLE PRECISION ELMEAN(37),ELMEAA(37)
20	INTEGER IELDPM(37,13),IELDPA(37,13)
21	*KEEP,ELASTY.
22	COMMON /ELASTY/ ELAST,IELIS,IELHM,IELNU,IELPI
23	DOUBLE PRECISION ELAST
24	INTEGER IELIS(20),IELHM(20),IELNU(20),IELPI(20)
25	*KEEP,INDICE.
26	COMMON /INDICE/ NNUCN,NKA0,NHYPN,NETA,NETAS,NPIZER,
27	* NNC,NKC,NHC,NPC,NCH,NNN,NKN,NHN,NET,NPN
28	INTEGER NNUCN(2:3),NKA0(2:3),NHYPN(2:3),NETA(2:3,1:4),
29	* NETAS(2:3),NPIZER(2:3),
30	* NNC,NKC,NHC,NPC,NCH,NNN,NKN,NHN,NET,NPN
31	*KEEP,INTER.
32	COMMON /INTER/ AVCH,AVCH3,DC0,DLOG,DMLOG,ECMDIF,ECMDPM,ELAB,
33	* FNEUT,FNEUT2,GNU,PLAB,POSC2,POSC3,POSN2,POSN3,
34	* RC3TO2,S,SEUGF,SEUGP,SLOG,SLOGSQ,SMLOG,
35	* WIDC2,WIDC3,WIDN2,WIDN3,YCM,YY0,ZN,
36	* IDIF,ITAR
37	DOUBLE PRECISION AVCH,AVCH3,DC0,DLOG,DMLOG,ECMDIF,ECMDPM,ELAB,
38	* FNEUT,FNEUT2,GNU,PLAB,POSC2,POSC3,POSN2,POSN3,
39	* RC3TO2,S,SEUGF,SEUGP,SLOG,SLOGSQ,SMLOG,
40	* WIDC2,WIDC3,WIDN2,WIDN3,YCM,YY0,ZN
41	INTEGER IDIF,ITAR
42	*KEEP,ISTA.
43	COMMON /ISTA/ IFINET,IFINNU,IFINKA,IFINPI,IFINHY
44	INTEGER IFINET,IFINNU,IFINKA,IFINPI,IFINHY
45	*KEEP,LEPAR.
46	COMMON /LEPAR/ LEPAR1,LEPAR2,LASTPI,NRESPC,NRESPN,NCPLUS
47	INTEGER LEPAR1,LEPAR2,LASTPI,NRESPC,NRESPN,NCPLUS
48	*KEEP,MULT.
49	COMMON /MULT/ EKINL,MSMM,MULTMA,MULTOT
50	DOUBLE PRECISION EKINL
51	INTEGER MSMM,MULTMA(37,13),MULTOT(37,13)
52	*KEEP,NEWPAR.
53	COMMON /NEWPAR/ EA,PT2,PX,PY,TMAS,YR,ITYP,
54	* IA1,IA2,IB1,IB2,IC1,IC2,ID1,ID2,IE1,IE2,IF1,IF2,
55	* IG1,IG2,IH1,IH2,II1,II2,IJ1,NTOT
56	DOUBLE PRECISION EA(3000),PT2(3000),PX(3000),PY(3000),TMAS(3000),
57	* YR(3000)
58	INTEGER ITYP(3000),
59	* IA1,IA2,IB1,IB2,IC1,IC2,ID1,ID2,IE1,IE2,IF1,IF2,
60	* IG1,IG2,IH1,IH2,II1,II2,IJ1,NTOT
61	*KEEP,PAM.
62	COMMON /PAM/ PAMA,SIGNUM
63	DOUBLE PRECISION PAMA(6000),SIGNUM(6000)
64	*KEEP,PARPAR.
65	COMMON /PARPAR/ CURPAR,SECPAR,PRMPAR,OUTPAR,C,
66	* E00,E00PN,PTOT0,PTOT0N,THICKH,ITYPE,LEVL
67	DOUBLE PRECISION CURPAR(14),SECPAR(14),PRMPAR(14),OUTPAR(14),
68	* C(50),E00,E00PN,PTOT0,PTOT0N,THICKH
69	INTEGER ITYPE,LEVL
70	*KEEP,PARPAE.
71	DOUBLE PRECISION GAMMA,COSTHE,PHI,H,T,X,Y,CHI,BETA,GCM,ECM
72	EQUIVALENCE (CURPAR(2),GAMMA), (CURPAR(3),COSTHE),
73	* (CURPAR(4), PHI ), (CURPAR(5), H ),
74	* (CURPAR(6), T ), (CURPAR(7), X ),
75	* (CURPAR(8), Y ), (CURPAR(9), CHI ),
76	* (CURPAR(10),BETA), (CURPAR(11),GCM ),
77	* (CURPAR(12),ECM )
78	*KEEP,RANDPA.
79	COMMON /RANDPA/ FAC,U1,U2,RD,NSEQ,ISEED,KNOR
80	DOUBLE PRECISION FAC,U1,U2
81	REAL RD(3000)
82	INTEGER ISEED(103,10),NSEQ
83	LOGICAL KNOR
84	*KEEP,RATIOS.
85	COMMON /RATIOS/ RPI0R,RPIER,RPEKR,RPEKNR,PPICH,PPINCH,PPNKCH,
86	* ISEL,NEUTOT,NTOTEM
87	DOUBLE PRECISION RPI0R,RPIER,RPEKR,RPEKNR,PPICH,PPINCH,PPNKCH
88	INTEGER ISEL,NEUTOT,NTOTEM
89	*KEEP,RESON.
90	COMMON /RESON/ RDRES,RESRAN,IRESPAR
91	REAL RDRES(2),RESRAN(1000)
92	INTEGER IRESPAR
93
94	*KEEP,REST.
95	COMMON /REST/ CONTNE,TAR,LT
96	DOUBLE PRECISION CONTNE(3),TAR
97	INTEGER LT
98	*KEEP,RUNPAR.
99	COMMON /RUNPAR/ FIXHEI,THICK0,HILOECM,HILOELB,
100	* STEPFC,NRRUN,NSHOW,PATAPE,MONIIN,
101	* MONIOU,MDEBUG,NUCNUC,
102	* CETAPE,
103	* SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
104	* N1STTR,MDBASE,
105	* DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
106	* FIX1I,FMUADD,FNKG,FPRINT,FDBASE
107	* ,GHEISH,GHESIG
108	COMMON /RUNPAC/ DSN,HOST,USER
109	DOUBLE PRECISION FIXHEI,THICK0,HILOECM,HILOELB
110	REAL STEPFC
111	INTEGER NRRUN,NSHOW,PATAPE,MONIIN,MONIOU,MDEBUG,NUCNUC,
112	* SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
113	* N1STTR,MDBASE
114	INTEGER CETAPE
115	CHARACTER*79 DSN
116	CHARACTER*20 HOST,USER
117
118	LOGICAL DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
119	* FIX1I,FMUADD,FNKG,FPRINT,FDBASE
120	* ,GHEISH,GHESIG
121	*KEND.
122
123	C-----------------------------------------------------------------------
124
125	IF ( DEBUG ) WRITE(MDEBUG,444) (CURPAR(I),I=1,9)
126	444 FORMAT(' HDPM : CURPAR=',1P,9E10.3)
127
128	C SET ANTI-LEADER TO PROTON OR NEUTRON; TARGET IS ALWAYS NUCLEON
129	CALL RMMAR( RD,1,1 )
130	IF ( RD(1) .LE. CONTNE(LT) ) THEN
131	ITAR = 13
132	ELSE
133	ITAR = 14
134	ENDIF
135
136
137	C CALCULATE LAB AND CM ENERGY
138	IF ( ITYPE .NE. 1 ) THEN
139	ELAB = PAMA(ITYPE) * GAMMA
140	PLAB = ELAB * BETA
141	S = PAMA(ITYPE)2 + PAMA(ITAR)2 + 2.D0PAMA(ITAR)ELAB
142	ELSE
143	C FOR GAMMA-INDUCED REACTION TAKE PI(0) AS LEADING PARTICLE
144	ITYPE = 7
145	ELAB = GAMMA
146	PLAB = ELAB
147	S = PAMA(ITAR)*2 + 2.D0PAMA(ITAR)*ELAB
148	ENDIF
149
150	ECMDPM = SQRT(S)
151	IF ( DEBUG ) WRITE(MDEBUG,*) 'HDPM : ITYPE,ELAB,PLAB,S,ECMDPM=',
152	* ITYPE,SNGL(ELAB),SNGL(PLAB),SNGL(S),SNGL(ECMDPM)
153
154	C LN(S), LN(S)**2 AND RAPIDITY OF C. M. SYSTEM IN LAB
155	SLOG = LOG(S)
156	SLOGSQ = SLOG**2
157	SMLOG = LOG( 2.D0 * PAMA(ITAR) * ELAB )
158	ELABLG = LOG(ELAB)
159	EPLUSP = ELAB + PLAB
160	* YCM = 0.5D0 * LOG( (ELAB+PAMA(ITAR)+PLAB)/(ELAB+PAMA(ITAR)-PLAB) )
161	YCM = 0.5D0 * LOG( (EPLUSP*2 +PAMA(ITAR)EPLUSP)/
162	* (PAMA(ITYPE)*2+PAMA(ITAR)EPLUSP) )
163	IF ( DEBUG ) WRITE(MDEBUG,*)'HDPM : SLOG,SLOGSQ,YCM=',
164	* SNGL(SLOG),SNGL(SLOGSQ),SNGL(YCM)
165
166	C-----------------------------------------------------------------------
167	C RETURN POINT IF CALCULATION OF PARTICLES GOES WRONG
168	1 CONTINUE
169
170	IF ( ITYPE .NE. 7 ) THEN
171	C CHOOSE NUMBER OF INTERACTIONS IN TARGET
172	CALL TARINT
173	ELSE
174	C FOR GAMMA-INDUCED REACTIONS TAKE ALWAYS ONE COLLISION
175	GNU = 1.D0
176	ENDIF
177
178	C-----------------------------------------------------------------------
179	C NO DIFFRACTION IF
180	C OR THE NUMBER OF INTERACTIONS IN TARGET IS CHOSEN RANDOMLY
181	C AND MORE THAN ONE INTERACTION TAKES PLACE
182	C OR PRIMARY PARTICLE IS GAMMA (PI0)
183	C NOW NFLDIF DECIDES WHETHER DIFFRACTIVE PROCESS POSSIBLE OR NOT
184	IF ( ( NFLAIN.EQ.0 .AND. GNU.GT.1.D0 .AND. NFLDIF.EQ.0 )
185	* .OR. ( ITYPE .EQ. 7 ) ) THEN
186	IDIF = 0
187	ELSE
188	C SET DIFFRACTION FLAG IF RANDOM NUMBER < PROBABILITY
189	CALL RMMAR( RD,1,1 )
190	C IDIF IS 0 : NO DIFFRACTION ; IDIF IS 1 : DIFFRACTION
191	C DIFFRACTION RISES WITH ENERGY AND SATURATES AT 10000 GEV
192	C ### DAS TUT ES ABER NICHT: ES IST KONSTANT 0.15 (SIEHE DPFUNC) !!!!
193	IF ( RD(1) .GT. DPFUNC(ECMDPM) ) THEN
194	IDIF = 0
195	ELSE
196	IDIF = 1
197	ENDIF
198	ENDIF
199
200
201	C PRINTOUT FOR DEBUG
202	IF ( DEBUG ) THEN
203	WRITE(MDEBUG,*) ' DIFFRACTIVE INTERACTION (0/1) = ',IDIF
204	ENDIF
205
206	C SET COUNTER FOR REPEAT TO 0
207	NREPRD = 0
208
209	C GENERATION OF INTERACTION
210	1919 CONTINUE
211
212	C FLAG TO CHECK NUMBER OF SECONDARIES;
213	C IS CHANGED TO 1 IF SECONDARY MULTIPLICITY IS LOW
214	ISEL = 0
215	C SET LEADING PARTICLE TO INCOMING PARTICLE AND ANTI-LEADER TO NUCLEON
216	C (AS IT COMES FROM TARGET NUCLEUS) BOTH MAY BE CHANGED BY LEPACX
217	LEPAR1 = ITYPE
218	LEPAR2 = ITAR
219
220	IF ( IDIF .EQ. 0 ) THEN
221	C-----------------------------------------------------------------------
222	C NON SINGLE DIFFRACTIVE PROCESS STARTS HERE
223
224	CALL NSD
225	C CHARGE EXCHANGE ENABLED? EXCHANGE LEADER AND ANTI-LEADER
226	LASTPI = 0
227	NRESPC = 0
228	NRESPN = 0
229	NCPLUS = 0
230	IF ( NFLCHE .EQ. 0 ) THEN
231	CALL LEPACX( ECMDPM,ELABLG,LEPAR1,1 )
232	CALL LEPACX( ECMDPM,ELABLG,LEPAR2,2 )
233	ENDIF
234	1921 CONTINUE
235	CALL RNEGBI( NCH,AVCH,ECMDPM )
236	C NCH IS # OF ALL CHARGED PARTICLES INCLUDING EXCESS FROM TARGET
237	IF ( NCH .LT. 1 ) THEN
238	IF ( LEPAR1 .LT. 50 .OR. LEPAR2 .LT. 50 ) THEN
239	NREPRD = NREPRD + 1
240	IF ( NREPRD .GT. 10 ) GOTO 1
241	GOTO 1921
242	ELSE
243	C INTERACTION IS ONLY RESONANCE PRODUCTION
244	ISEL = 1
245	ENDIF
246	ENDIF
247	C WIDTH PLATEAU FOR CLUSTERS AND FOR CALCULATION OF CENTR.RAP.DENSITY
248	DELRAP = 0.6722D0 * (2.95D0 + 0.0302D0 * SLOG)
249	C SET RSLOG FOR CALCULATION OF PARTICLE RATIOS
250	RSLOG = SLOG
251	C AVERAGE TRANSVERSE MOMENTUM
252	CALL AVEPT( ECMDPM,SLOG )
253
254	ELSE
255	C-----------------------------------------------------------------------
256	C SINGLE DIFFRACTIVE PROCESS STARTS HERE
257
258	1920 CONTINUE
259	CALL DIFRAC( NRETDF )
260	IF ( NRETDF .EQ. 1 ) GOTO 1
261	C CHARGE EXCHANGE ENABLED? EXCHANGE CHARGE OF DIFFRACTING PARTICLE
262	LASTPI = 0
263	NRESPC = 0
264	NRESPN = 0
265	NCPLUS = 0
266	IF ( NFLCHE .EQ. 0 ) THEN
267	IF ( YY0 .GT. 0.D0 ) THEN
268	C PROJECTILE DIFFRACTION
269	CALL LEPACX( ECMDIF,DMLOG,LEPAR1,1 )
270	ELSE
271	C TARGET DIFFRACTION
272	CALL LEPACX( ECMDIF,DMLOG,LEPAR2,2 )
273	ENDIF
274	ENDIF
275	C FLUCTUATION OF MULTIPLICITY ACCORDING TO NEG.BIN. DISTRIBUTION
276	CALL RNEGBI( NCH,AVCH,ECMDIF )
277	C REPEAT CALCULATION AS SOMETHING WENT WRONG
278	IF ( NCH .LT. 1 ) THEN
279	IF ( (YY0 .GT. 0.D0 .AND. LEPAR1 .LT. 50) .OR.
280	* (YY0 .LT. 0.D0 .AND. LEPAR2 .LT. 50) ) THEN
281	NREPRD = NREPRD + 1
282	IF ( NREPRD .GT. 10 ) GOTO 1
283	GOTO 1920
284	ELSE
285	C DIFFRACTIVE INTERACTION IS ONLY RESONANCE PRODUCTION
286	ISEL = 1
287	ENDIF
288	ENDIF
289	C SET RSLOG FOR CALCULATION OF PARTICLE RATIOS
290	RSLOG = DLOG
291	C HERE WE USE ECMDPM, BECAUSE THE MOMENTUM TRANSFER IS DEPENDENT
292	C ON THE ENERGY OF THE TOTAL SYSTEM AND NOT ON THE DIFFRACTING MASS
293	CALL AVEPT( ECMDPM,SLOG )
294
295	ENDIF
296
297	C-----------------------------------------------------------------------
298	C NOW FOR NSD AND DIFFRACTIVE PROCESSES
299
300	C IN CASE OF LOW MULTIPLICITY SET FLAG ISEL
301	IF ( NCH .LE. 2 ) ISEL=1
302	C FNCH IS FLUCTUATING TOT.NUMBER OF CHARGED PARTICLES FOR ALL 3 STRINGS
303	FNCH = DBLE(NCH)
304	C RATIO ALL CHARGED PARTICLES WITH FLUCTUATION/WITHOUT FLUCTUATION
305	XZ = FNCH / AVCH
306	C FNCH3 IS FLUCTUATING NUMBER OF CHARGED PARTICLES FOR 3RD STRING
307	FNCH3 = XZ * AVCH3
308	C FNCH2 IS FLUCTUATING NUMBER OF CHARGED PARTICLES 1ST AND 2ND STRING
309	FNCH2 = FNCH - FNCH3
310	C RC3TO2 IS RATIO (CHARGED 3RD STRING)/(CHARGED 1ST AND 2ND STRING)
311	IF ( FNCH2 .NE. 0.D0 ) THEN
312	RC3TO2 = FNCH3 / FNCH2
313	ELSE
314	RC3TO2 = 0.D0
315	ENDIF
316	IF ( DEBUG ) WRITE(MDEBUG,*) ' FNCH,FNCH2,FNCH3,RC3TO2=',
317	* SNGL(FNCH),SNGL(FNCH2),SNGL(FNCH3),SNGL(RC3TO2)
318
319	C IS NUMBER OF NEUTRALS FLUCTUATING AS NUMBER OF CHARGED ?
320	IF ( NFLPIF .EQ. 0 .OR. IDIF .EQ. 1 .OR. ECMDPM .LT. 60.D0 ) THEN
321	C SET NUMBER OF GAMMAS ACCORDING TO NEG. BIN. VARIABLE XZ
322	C AS NUMBER OF NEUTRALS FLUCTUATES AS CHARGED.
323	SEUGF = SEUGP * XZ
324	ZG = XZ
325	ELSE
326	C NFLPIF IS 1 MEANS: # OF PI(0) FLUCTUATES AS MEASURED AT COLLIDER
327	IF ( ECMDPM .LT. 200.D0 ) THEN
328	SEUGF = SEUGP * XZ
329	* SEUGF = (0.0786D0SLOG-0.010D0)FNCH2 + (0.391D0*SLOG+0.305D0)
330	ELSE
331	C DETERMINE NEW NUMBER OF GAMMAS WITH FLUCTUATION AROUND SEUGP*XZ
332	AGR = EXP(-XZ)
333	DGR = SEUGP * XZ * (0.9823D0 - 0.3756D0 * AGR)
334	SGS = DGR * (0.14718D0 + 2.53213D0 * AGR)
335	723 CONTINUE
336	SEUGF = 0.88D0 * RANNOR(DGR,SGS)
337	IF ( SEUGF .LT. 1.D0 ) GOTO 723
338	ENDIF
339	C SET NEGATIVE BINOMIAL VARIABLE ZG FOR GAMMAS
340	ZG = SEUGF / SEUGP
341	ENDIF
342	SEUGF = MAX( 1.D0, SEUGF )
343	IF ( DEBUG ) WRITE(MDEBUG,*) 'HDPM :XZ,ZG,SEUGF=',
344	* SNGL(XZ),SNGL(ZG),SNGL(SEUGF)
345
346	C-----------------------------------------------------------------------
347	C RATIO ALL-NUCLEON/ALL-CHARGED
348	C PARAMETRISATION FROM UA5, NUCL. PHYS. B291 (1987) 445 EQ.(2.4)
349	RNUCCH = MAX( 0.D0, -0.008D0 + 0.00865D0 * RSLOG )
350	C NUMBER FOR DIRECT NEUTRON/ANTINEUTRON PRODUCTION 1ST AND 2ND STRING
351	C MULTIPLY BY 0.5 BECAUSE RATIO RNUCCH GIVES (ALL-NUCL)/(ALL-CHARGED)
352	C AND HERE ONLY THE NEUTRON-ANTINEUTRONS ARE COUNTED
353	FNUCN = 0.5D0 * RNUCCH * FNCH2
354	C RATIO (ALL CHARGED SIGMAS)/(ALL CHARGED) IS 1/3 OF ALL STRANGE BARYON
355	C PARAMETRISATION FORM UA5, NUCL. PHYS. B291 (1987) 445 EQ.(2.5)
356	RHYPCH = MAX( 0.D0, (-0.007D0 + 0.0028D0 * RSLOG) * OB3 )
357	C NEUTRAL STRANGE BARYONS ARE DOUBLE OF CHARGED STRANGE BARYONS
358	FHYPN = 2.D0 * RHYPCH * FNCH2
359	C CORRECT NUMBER OF GAMMAS FROM NEUTRAL HYPERON DECAY S0-->L+GAMMA
360	SEUGFC = MAX( 0.D0, SEUGF - 0.5D0 * FHYPN )
361	C RATIO CHARGED-KAON/CHARGED PIONS
362	C PARAMETRISATION FROM UA5, NUCL. PHYS. B291 (1987) 445 EQ.(2.7)
363	RKPI = MAX (0.D0, 0.024D0 + 0.0062D0 * RSLOG )
364	C RKCH IS RATIO (CHARGED-KAON)/(ALL-CHARGED) DERIVED FROM RKPI;
365	C THE FACTOR 0.5 IN FRONT OF RNUCCH IS BECAUSE ONLY HALF OF NUCLEONS
366	C ARE P/PBAR. THE 1.17 IS AN APROXIMATE CONVERSION FACTOR FROM
367	C (ALL-NUCL)/(ALL-CHARGED) TO (ALL-NUCL)/(CHARGED-PI), WHICH IS A BIT
368	C ENERGY DEPENDENT (1.14 ...1.21) SEE GEICH-GIMBEL TABLE 7.1
369	RKCH = RKPI / (1.D0 + RKPI + (0.5D0RNUCCH+RHYPCH) 1.17D0)
370	C K0/K0-BAR FOR 1ST AND 2ND STRING
371	C NEUTRAL KAONS ARE PRODUCED WITH THE SAME RATE AS CHARGED KAONS
372	FKA0 = RKCH * FNCH2
373	C RATIO ETA/PI(0) IS ASSUMED TO BE INDEPENDENT OF ENERGY = 0.19
374	C SEE: ANSORGE ET AL. (UA5-COLLABORATION) Z.PHYS.C43(1989)75
375	* RETPI0 = 0.19D0
376	C RATIO ETA/PI(0) IS ASSUMED TO BE DEPENDENT ON ENERGY
377	C SEE: GEICH-GIMBEL,INT.J.MOD.PHYS.A4(1989)1527 TAB.7.1
378	C HECK'S FIT: RETPI0 IS 0.06 + 0.006RSLOG + 0.0011RSLOG**2
379	RETPI0 = 0.06D0 + 0.006D0 * RSLOG + 0.0011D0 * RSLOG**2
380	C AUXIL1 IS FRACTION OF PI(0)/(PI(0)+ETA)
381	AUXIL1 = 1.D0 / (1.D0 + RETPI0)
382	C NUMBER OF GAMMAS FROM PI(0) IS 2, FROM ETA IS 3.216 IN AVERAGE;
383	C AUXIL2 IS NUMBER OF GAMMA-PRODUCING-PARTICLES: PI(0) AND ETA
384	AUXIL2 = SEUGFC / ( AUXIL1 * 2.D0 + (1.D0 - AUXIL1) * 3.216D0 )
385	FETA = (1.D0 - AUXIL1) * AUXIL2
386	FPI0 = AUXIL1 * AUXIL2
387	C CORRECT FPI0 BY DECAYS OF STRANGE BARYONS; NEUTRAL: FHYPN*0.357
388	C CHARGED: 0.5FNCH2RHYPCH0.5157; IT YIELDS FHYPN(0.357+0.12893)
389	FPI0 = MAX( 0.D0, FPI0 - FHYPN * 0.486D0 )
390	C SUMMED NEUTRAL PARTICLES FOR 1ST AND 2ND STRING
391	FNEUT2 = FNUCN + FKA0 + FHYPN + FETA + FPI0
392	C NEUTRAL PARTICLES FROM 3RD STRING
393	FNEUT3 = RC3TO2 * FNEUT2
394	C TOTAL NUMBER OF NEUTRALS
395	FNEUT = FNEUT2 + FNEUT3
396	NEUTOT = NINT( FNEUT )
397	C CALCULATE TOTAL NUMBER OF PARTICLES TO BE CREATED
398	NTOTEM = NCH + NEUTOT
399	IF ( DEBUG ) WRITE(MDEBUG,*)
400	* ' FNUCN,FKA0,FHYPN,FETA,FPI0,FNEUT2,FNEUT3,NTOTEM=',
401	* SNGL(FNUCN),SNGL(FKA0),SNGL(FHYPN),SNGL(FETA),SNGL(FPI0),
402	* SNGL(FNEUT2),SNGL(FNEUT3),NTOTEM
403	C LIMIT OF SECONDARIES PRODUCED (GIVEN BY SIZE OF ARRAY : 3000)
404	C LIMIT IS ARRAY SIZE - SIZE OF LARGEST TARGET NUCLEUS(40)
405	IF ( NTOTEM .GE. 2956 ) THEN
406	WRITE(MONIOU,*) 'HDPM : REJECT EVENT WITH ',NTOTEM,
407	* ' SECONDARIES'
408	GOTO 1
409	ENDIF
410	C SPECIAL TREATMENT IF MULTIPLICITY IS TOO LOW
411	IF ( NTOTEM .LE. 3 ) ISEL = 1
412
413	C FRACTION OF THE VARIOUS NEUTRAL PARTICLES (NN, K(0), L+S0 AS PAIRS)
414	C NORMALIZE WITH THE SUM OF ALL NEUTRAL PARTICLES
415	FNORML = 1.D0 / ( 0.5D0 * (FNUCN+FKA0+FHYPN) + FETA + FPI0 )
416	RNUCNR = FNUCN * FNORML * 0.5D0
417	RKA0R = FKA0 * FNORML * 0.5D0
418	RHYPNR = FHYPN * FNORML * 0.5D0
419	RETAR = FETA * FNORML
420	RPI0R = FPI0 * FNORML
421	C CUMULATED RATIOS (NN, K(0), LAMBDA+SIGMA0 AS PAIRS)
422	RPIER = RPI0R + RETAR
423	RPEKR = RPIER + RKA0R
424	RPEKNR = RPEKR + RNUCNR
425	C THEN THE REMAINDER (1-RPEKNR) MUST BE NEUTRAL HYPERON PAIRS
426	IF ( DEBUG ) WRITE(MDEBUG,*)
427	* ' RPI0R,RETAR,RKA0R,RNUCNR,RHYPNR,FNORML=',
428	* SNGL(RPI0R),SNGL(RETAR),SNGL(RKA0R),SNGL(RNUCNR),SNGL(RHYPNR),
429	* SNGL(FNORML)
430
431	C PROBABILITY TO PRODUCE CHARGED PIONS IS PROBABILITY NOT TO PRODUCE
432	C CHARGED KAONS OR PROTONS OR CHARGED HYPERONS, WHERE PROTON/ANTIPROTON
433	C IS HALF OF (ALL-NUCL)/(ALL-CHARGED)
434	AUXIL = RKCH + 0.5D0 * RNUCCH + RHYPCH
435	AUXIL3 = 1.D0 - AUXIL
436	C RENORMALIZATION AS P/P_BAR, K+-, AND HYPERONS ARE PRODUCED IN PAIRS
437	C AUXIL2 IS INVERSE OF NORMALISATION
438	AUXIL2 = 1.D0 / (1.D0 - 0.5D0 * AUXIL)
439	C CUMULATED PROBABILITIES (PP, K+-, SIGMA+- AS PAIRS)
440	PPICH = AUXIL3 * AUXIL2
441	PPINCH = PPICH + 0.25D0 * RNUCCH * AUXIL2
442	PPNKCH = PPINCH + 0.5D0 * RKCH * AUXIL2
443	C THEN THE REMAINDER (1-PPNKCH) MUST BE CHARGED HYPERON PAIRS
444	IF ( DEBUG ) WRITE(MDEBUG,*) ' PPICH,PPINCH,PPNKCH=',
445	* SNGL(PPICH),SNGL(PPINCH),SNGL(PPNKCH)
446
447	C NOW SELECT HOW MANY PARTICLES OF EACH TYPE ARE PRODUCED
448	CALL PARNUM( INUMFL )
449	IF ( INUMFL .NE. 0 ) GOTO 1919
450
451	C DEFINE PARTICLE NUMBERS WHERE SPECIAL RAPIDITY IS CALCULATED
452	C FOR PARTICLES FROM TARGET (THIRD STRING)
453	PPP = RC3TO2 / (1.D0+RC3TO2)
454	C NUMBER OF PARTICLES IN PROTON ANTIPROTON PAIRS FROM TARGET
455	ITA = NINT(PPP * 2.D0 * NNC)
456	C NUMBER OF PARTICLES IN K+ K- PAIRS FROM TARGET
457	ITB = NINT(PPP * 2.D0 * NKC)
458	C NUMBER OF PARTICLES IN SIGMA+ SIGMA- PAIRS FROM TARGET
459	ITC = NINT(PPP * 2.D0 * NHC)
460	C NUMBER OF PI+ PI- FROM TARGET
461	ITD = NINT(PPP * NPC )
462	C CALCULATE BOUNDARIES
463	IA1 = 2
464	IA2 = IA1 + ITA
465	IB1 = IA1 + 2 * NNC
466	IB2 = IB1 + ITB
467	IC1 = IB1 + 2 * NKC
468	IC2 = IC1 + ITC
469	ID1 = IC1 + 2 * NHC
470	ID2 = ID1 + ITD
471	IE1 = ID1 + NPC
472	C NUMBER OF PARTICLES IN NEUTRON ANTINEUTRON PAIRS FROM TARGET
473	IE2 = IE1 + 2 * NNUCN(3)
474	IF1 = IE1 + 2 * NNN
475	C NUMBER OF PARTICLES IN K0S K0L PAIRS FROM TARGET
476	IF2 = IF1 + 2 * NKA0(3)
477	IG1 = IF1 + 2 * NKN
478	C NUMBER OF PARTICLES IN NEUTRAL HYPERON PAIRS FROM TARGET
479	IG2 = IG1 + 2 * NHYPN(3)
480	IH1 = IG1 + 2 * NHN
481	C NUMBER OF ETA FROM TARGET
482	IH2 = IH1 + NETAS(3)
483	II1 = IH1 + NET
484	C NUMBER OF PI(0) FROM TARGET
485	II2 = II1 + NPIZER(3)
486	IJ1 = II1 + NPN
487	IF ( DEBUG ) THEN
488	WRITE(MDEBUG,*) ' CHARGED FROM TARGET:',ITA,ITB,ITC,ITD
489	WRITE(MDEBUG,*) ' NEUTRAL FROM TARGET:',
490	* 2NNUCN(3),2NKA0(3),2*NHYPN(3),NETAS(3),NPIZER(3)
491	WRITE(MDEBUG,*) ' NTOTEM,IJ1=',NTOTEM,IJ1
492	ENDIF
493	C REDEFINE TOTAL NUMBER OF SECONDARY PARTICLES : NTOTEM
494	C BY CHARGE EXCHANGE AND RESONANCE FORMATION THIS NUMBER MAY BE ALTERED
495	NTOTEM = IJ1 - 2
496
497	C-----------------------------------------------------------------------
498	C RATIO OF RAPIDITY DENSITY TO MEAN PSEUDORAPIDITY IN CENTER
499	C PARAMETRISATION SEE CAPDEVIELLE, J.PHYS.G:NUCL.PHYS.15(1989)909,EQ.6
500	IF ( XZ .LT. 1.5D0 ) THEN
501	RDS = (0.24396D0 + 0.70150424D0 * XZ)**2
502	ELSE
503	RDS = (0.55685D0 + 0.48664753D0 * XZ)**2
504	ENDIF
505	C CALCULATE NOW: DN/DY AT Y = 0; DC0 IS AVERAGE PSEUDORAPIDITY DENSITY
506	C TRAP IS RATIO (RAPID.DENS.)/(PSEUDORAP.DENS.) IN CENTER OF RAPIDITY
507	TRAP = 1.25D0
508	IF ( IDIF .EQ. 0 .AND. ECMDPM .GT. 19.4D0 )
509	* TRAP = MAX( 1.D0, 1.28852D0 - 0.0065D0 * SMLOG )
510	DCN2 = DC0 * RDS * TRAP
511	IF ( DEBUG ) WRITE(MDEBUG,*) ' RDS,TRAP,DCN2=',
512	* SNGL(RDS),SNGL(TRAP),SNGL(DCN2)
513	C AMPLITUDE OF GAUSSIAN 1ST AND 2ND STRING
514	ATG2 = FNCH2 / (5.0132566D0 * WIDC2)
515	C NEW DEFINITION OF POSITION BASED ON SEMI INCLUSIVE DATA
516	SQ2 = 2.D0 * ATG2 / DCN2
517	C FINAL POSITION OF GAUSSIAN; WIDTH WIDC2 IS UNCHANGED
518	IF ( SQ2 .GT. 1.D0 ) POSC2 = WIDC2 * SQRT( 2.D0*LOG(SQ2) )
519	C DENSITY OF CHARGED IN EXCESS FROM TARGET IN CENTER OF RAPIDITY
520	DCN3 = 0.5D0 * (GNU - 1.D0) * DCN2
521	IF (DEBUG) WRITE(MDEBUG,*) ' SQ2,POSC2,DCN3=',
522	* SNGL(SQ2),SNGL(POSC2),SNGL(DCN3)
523	IF ( DCN3 .GT. 0.D0 ) THEN
524	C AMPLITUDE 3RD GAUSSIAN
525	ATG3 = FNCH3 / (5.0132566D0 * WIDC3)
526	C AMPLITUDE IS DIVIDED BY DENSITY FOR GETTING CENTER OF 3RD GAUSSIAN
527	SQ3 = 2.D0 * ATG3 / DCN3
528	C CHECK IF ADDITIVE MULTIPLICITY IS TOO LOW
529	IF ( SQ3 .GT. 1.D0 ) POSC3 = WIDC3 * SQRT( 2.D0*LOG(SQ3) )
530	IF (DEBUG) WRITE(MDEBUG,*)' SQ3,POSC3=',SNGL(SQ3),SNGL(POSC3)
531	ENDIF
532
533	C NFLPI0 .EQ. 0 MEANS TREAT PI(0) RAPIDITY ACCORDING TO COLLIDER DATA
534	IF ( NFLPI0 .EQ. 0 ) THEN
535	C RATIO OF RAPIDITY DENSITY TO MEAN PSEUDORAPIDITY AT CENTER WITH Z<1.5
536	IF ( ZG .LT. 1.5D0 ) THEN
537	RDG = (0.24396D0 + 0.70150424D0 * ZG)**2
538	ELSE
539	RDG = (0.55685D0 + 0.48664753D0 * ZG)**2
540	ENDIF
541	C GAMMAS USE RATIO TRAG TO CALCULATE RATIO OF RAPIDITY TO
542	C PSEUDO RAPIDITY DENSITY IN CENTER (TRAG = 1.1 * 0.5 ).
543	C FACTOR 0.5 COMES FROM RATIO NEUTRAL/CHARGED, AS WE USE DC0, WHICH
544	C IS AVERAGE PSEUDORAPIDITY DENSITY FOR CHARGED PIONS
545	TRAG = 0.55D0
546	IF ( IDIF .EQ. 0 ) THEN
547	IF ( ECMDPM .GT. 19.4D0 )
548	* TRAG = MAX( 0.4D0, 0.6658D0 - 0.01954D0 * SMLOG )
549	IF ( ECMDPM .LE. 50.D0 ) THEN
550	DCG = DC0 * RDG * TRAG
551	ELSEIF ( ECMDPM .LE. 200.D0 ) THEN
552	DCG = DC0 * RDG * TRAG * (1.D0 + 0.18D0 * LOG(ECMDPM/50.D0))
553	ELSE
554	DCG = DC0 * RDG * TRAG * 1.25D0
555	ENDIF
556	ELSE
557	DCG = DC0 * RDG * TRAG
558	ENDIF
559	C DEFINE WIDTH OF STRINGS FOR NEUTRAL PIONS AND ETAS
560	WIDN2 = WIDC2 * MIN( 1.D0, 1.12275D0 - 0.0208D0 * RSLOG )
561	C NEW DEFINITION OF CENTER OF GAUSSIAN BASED ON SEMI INCLUSIVE DATA
562	C USING AMPLITUDE OF THE GAUSSIAN FOR NEUTRALS
563	AUXIL = 2.D0 / (5.0132566D0 * WIDN2 * DCG)
564	C TOTAL MULTIPLICITY USED FOR 1ST AND 2ND STRING OF PI(0) AND ETA
565	C IS GIVEN BY THEIR NUMBERS. ANALOGOUS FOR 3RD STRING
566	SP2 = DBLE ( NPIZER(2)+NETAS(2)) * AUXIL
567	C FINAL CENTER OF GAUSSIANS FOR PI(0) AND ETA (WIDC2 IS UNCHANGED)
568	IF ( SP2 .GT. 1.D0 ) THEN
569	POSN2 = WIDN2 * SQRT( 2.D0 * LOG(SP2) )
570	ELSE
571	POSN2 = POSC2
572	ENDIF
573	WIDN3 = WIDN2
574	SP3 = DBLE(NPIZER(3)+NETAS(3)) * AUXIL
575	IF ( SP3 .GT. 1.D0 ) THEN
576	POSN3 = WIDN3 * SQRT( 2.D0 * LOG(SP3) )
577	ELSE
578	POSN3 = POSC3
579	ENDIF
580	ELSE
581	C NFLPI0 .EQ. 1 MEANS RAPIDITY OF PI(0) AND ETA SAME AS THAT OF CHARGED
582	POSN2 = POSC2
583	WIDN2 = WIDC2
584	POSN3 = POSC3
585	WIDN3 = WIDC3
586	ENDIF
587	IF ( DEBUG ) WRITE(MDEBUG,*)
588	* ' ZG,RDG,DCG,SP2,SP3,POSN2,POSN3,WIDN2 =',
589	* SNGL(ZG),SNGL(RDG),SNGL(DCG),SNGL(SP2),SNGL(SP3),SNGL(POSN2),
590	* SNGL(POSN3),SNGL(WIDN2)
591
592	C-----------------------------------------------------------------------
593	NREPR1 = 0
594	C RETURN POINT. NUMBERS OF PARTICLES REMAIN UNCHANGED FOR NEXT TRY,
595	C BUT INDIVIDUAL RAPIDITIES GET NEW VALUES.
596	C START FROM BEGINNING IF NO MATCH AFTER 20 TRIES
597	30 CONTINUE
598	NREPR1 = NREPR1 + 1
599	IF ( NREPR1 .GT. 20 ) THEN
600	IF ( IDIF .EQ. 1 .AND. NREPRD .LE. 10 ) GOTO 1919
601	GOTO 1
602	ENDIF
603
604	C FOR TOTAL NUMBER OF PARTICLES ADD 2 FOR LEADER AND ANTILEADER
605	NTOT = NTOTEM + 2
606
607	C PRODUCTION OF INDIVIDUAL RAPIDITIES FOR ALL SECONDARY PARTICLES
608	CALL PARRAP
609	CC IF ( DEBUG ) THEN
610	CC WRITE (MDEBUG,*) ' RAPIDITIES:'
611	CC WRITE (MDEBUG,134) (I,YR(I), I=3,NTOT)
612	C134 FORMAT(' ',1P, (1X, I4, 5X, G13.6 ))
613	CC ENDIF
614
615
616	C CALCULATION OF CENTRAL RAPIDITY WITHOUT (ANTI)LEADER
617	C MULTIPLICITY IN CENTER OF RAPIDITY DISTRIBUTION
618	IZN = 0.D0
619	IF ( IDIF .EQ. 0 ) THEN
620	DO 111 I = 3,NTOT
621	IF ( ABS(YR(I)) .LT. DELRAP ) IZN = IZN + 1
622	111 CONTINUE
623	IF ( IZN .LT. 1 ) THEN
624	IF ( ISEL .EQ. 0 ) GOTO 30
625	C IN CASE OF FEW PARTICLES, SET PARTICLE NUMBER IN PLATEAU TO 1
626	IZN = 1
627	ENDIF
628	C CENTRAL RAPIDITY DENSITY FOR CHARGED PARTICLES
629	IF ( NTOTEM .GE. 1 ) THEN
630	ZNC = MAX( 1.1D0, DBLE(NCH)IZN/(DBLE(NTOTEM)2.D0*DELRAP) )
631	ELSE
632	ZNC = 1.1D0
633	ENDIF
634	ELSE
635	C DIFFRACTION: SHIFT RAPIDITIES + TAKE CENT.RAP.DENS. FROM PARAMETRISAT
636	DO 112 I = 3,NTOT
637	YR(I) = YR(I) + YY0
638	112 CONTINUE
639	ZNC = MAX( 1.1D0, DCN2 )
640	ENDIF
641
642	C ZN ACCOUNTS FOR THE RISE OF PT WITH CENTRAL RAP.DENSITY. THE FORMULA
643	C IS A FIT TO UA1 VALUES OF ARNISON ET AL, PHYS.LETT.B118(1982)167
644	C REGARD, THAT OUR ZN IS DEFINED DIFFERENT FROM LITERATURE N BY 1
645	C - - - - - -
646	C MODIFICATION AFTER J.N. CAPDEVIELLE, (DEC.96)
647	IF ( ECMDPM .LE. 500.D0 ) THEN
648	ZN = MAX( 1.00001D0, 3.669D0 / ZNC**0.435D0 + 6.4D0 )
649	ELSE
650	C TAKE INTO ACCOUNT THE RESULTS OF UA1/MIMI EXPERIMENT
651	IF ( ZNC .GE. 3.D0 ) THEN
652	ZN = 1.D0 /(ZNC*0.004111D0 + 0.145D0)+3.D0
653	ELSE
654	C FOR ROCH < 3.00 (MIMI) (TO BE USED IN PTRAM)
655	ZM = 0.0033D0 * (ZNC-1.56D0)**2 + 0.406D0
656	ZN = 2.64D0/ZM + 3.D0
657	ENDIF
658	ENDIF
659	C - - - - - -
660	C NOW SET PARTICLE TYPE AND TRANSV. MOMENTA FOR NEW PARTICLES IN PPARAM
661	C SET ALSO TRANSVERSE MASS FOR ALL PARTICLES (INCL. LEADER+ANTILEADER)
662	CALL PPARAM
663
664	IF ( IDIF .EQ. 0 ) THEN
665	C NOW SET THE RAPIDITY OF THE ANTILEADER ACCORDING TO THE DISTRIBUTION
666	C IN THE FEYNMAN X VARIABLE; SET THE RAPIDITY OF LEADER TO CONSUME
667	C THE REMAINDER OF ENERGY
668	CALL LEDENY( LEDEFL )
669	IF ( LEDEFL .NE. 0 ) THEN
670	IF ( DEBUG ) WRITE(MDEBUG,*) ' LEDEFL=',LEDEFL
671	GOTO 30
672	ENDIF
673
674	C CALCULATE FOR SINGLE COLLISION SYSTEM C.M. ENERGY + RAPIDITY SHIFT
675	IF ( GNU .LE. 1.D0 ) THEN
676	JGNU = 0.D0
677	DYGNU = 0.D0
678	ECMJAD = ECMDPM
679	ELSE
680	C MULTIPLE COLLISION IN TARGET
681	JGNU = NINT(GNU-1.D0)
682	C ADD ADDITIONALLY INTERACTING
683	C TARGET NUCLEONS TO GET CORRECT JADACH FILTERING
684	C CHOSE RANDOMLY WHETHER PROTON OR NEUTRON
685	CALL RMMAR( RD,JGNU,1 )
686	IPR = 0
687	INE = 0
688	TARMAS = PAMA(ITYP(2))
689	DO 114 I = 1,JGNU
690	NTOT = NTOT + 1
691	IF ( RD(I) .LE. .5D0 ) THEN
692	ITYP(NTOT) = 13
693	INE = INE + 1
694	ELSE
695	ITYP(NTOT) = 14
696	IPR = IPR + 1
697	ENDIF
698	TMAS(NTOT) = PAMA(ITYP(NTOT))
699	TARMAS = TARMAS + TMAS(NTOT)
700	EA(NTOT) = TMAS(NTOT)
701	PX(NTOT) = 0.D0
702	PY(NTOT) = 0.D0
703	PT2(NTOT) = 0.D0
704	114 CONTINUE
705
706	C CALCULATE C.M. ENERGY + RAPIDITY SHIFT
707	* YCMGNU = 0.5D0 * LOG( (ELAB+TARMAS+PLAB)/(ELAB+TARMAS-PLAB) )
708	YCMGNU = 0.5D0 * LOG( (EPLUSP*2 +TARMASEPLUSP)/
709	* (PAMA(ITYPE)*2+TARMASEPLUSP) )
710	DYGNU = YCM - YCMGNU
711
712	C CALCULATE RAPIDITIES OF ADDITIONALLY INTERACTING TARGET NUCLEONS
713	C IN THE CM SYSTEM OF NUCLEON-NUCLEON SYSTEM
714	DO 115 I = NTOT-JGNU+1,NTOT
715	YR(I) = - YCM
716	115 CONTINUE
717	C SHIFT RAPIDITIES INTO CM SYSTEM OF GNU+1 MASSES
718	DO 113 I = 1,NTOT
719	YR(I) = YR(I) + DYGNU
720	113 CONTINUE
721
722	C CENTER OF MASS ENERGY OF 1 PROJECTILE AND GNU TARGET NUCLEONS TO
723	C BE USED IN THE JADACH FILTER.
724	ECMJAD = SQRT( PAMA(ITYPE)2 + TARMAS2 + 2.D0TARMASELAB )
725
726	ENDIF
727
728	ELSE
729	C IN CASE OF DIFFRACTION SET THE RAPIDITY OF LEADER AND ANTILEADER
730	C IN SUBROUTINE LEADDF
731	DYGNU = 0.D0
732	ECMJAD = ECMDPM
733	CALL LEADDF( IFLGLD )
734	IF ( IFLGLD .NE. 0 ) THEN
735	IF ( DEBUG ) WRITE(MDEBUG,*) ' IFLGLD=',IFLGLD
736	GOTO 30
737	ENDIF
738	ENDIF
739
740	C CORRECT THE RAPIDITIES TO CONSERVE LONGITUDINAL MOMENTA AND ENERGY
741	C USING THE ALGORITHM OF JADACH (SIMPLIFIED VERSION BY R. ATTALLAH)
742	CALL JADACH( ECMJAD,JADFLG )
743	IF ( JADFLG .NE. 0 ) THEN
744	IF ( DEBUG ) WRITE(MDEBUG,*) ' JADFLG=', JADFLG
745	IF ( JADFLG .GT. 0 ) GOTO 30
746	IF ( JADFLG .LT. 0 ) THEN
747	NREPRD = NREPRD + 1
748	IF ( NREPRD .GT. 10 ) GOTO 1
749	GOTO 1919
750	ENDIF
751	ENDIF
752
753
754	C CALCULATE LAB ENERGIES OF SECONDARY PARTICLES FROM THE RAPIDITIES
755	C INCLUDING THE ADDITIONAL TARGET NUCLEONS
756	ETOT = 0.D0
757	DO 135 I = 1,NTOT
758	YR(I) = YR(I) + YCM - DYGNU
759	EA(I) = TMAS(I) * COSH( YR(I) )
760	ETOT = ETOT + EA(I)
761	135 CONTINUE
762
763	IF ( DEBUG ) WRITE(MDEBUG,136)
764	* (I,ITYP(I),PX(I),PY(I),YR(I),EA(I),I=1,NTOT)
765	136 FORMAT(' NO ITYP PX PY YR EA'/
766	* (' ',I4,I3,1X,1P,4G13.6) )
767
768	C-----------------------------------------------------------------------
769	C LOOP OVER ALL SECONDARY PARTICLES AND THE LEADING PARTICLE
770	C PUT THEM ON THE STACK
771	DO 139 LK = 5,8
772	SECPAR(LK) = CURPAR(LK)
773	139 CONTINUE
774
775	C PROCESS LOOP
776	DO 140 J = 1,NTOT
777	C REJECTION OF BACKWARD GOING PARTICLES
778	IF ( YR(J) .LE. 0.D0 ) THEN
779	IF ( DEBUG ) WRITE(MDEBUG,*)'HDPM : YR REJECT PARTICLE ',J
780	GOTO 140
781	ENDIF
782	C CALCULATE THE PROPERTIES OF ALL SECONDARIES
783	C PARTICLE TYPE
784	SECPAR(1) = ITYP(J)
785	C CALCULATE GAMMA FACTOR
786	SECPAR(2) = EA(J) / PAMA(ITYP(J))
787	C TOTAL MOMENTUM SQUARED
788	PTM = EA(J)2 - PAMA(ITYP(J))2
789	IF ( PT2(J) .GT. PTM ) THEN
790	IF ( DEBUG ) WRITE(MDEBUG,*)'HDPM : PT REJECT PARTICLE ',J
791	GOTO 140
792	ENDIF
793	C EMISSION ZENITH ANGLE AGAINST TRAJECTORY OF PROJECTILE
794	IF ( PTM .EQ. 0.D0 ) THEN
795	COSTET = 1.D0
796	ELSE
797	COSTET = SQRT( 1.D0 - PT2(J) / PTM )
798	ENDIF
799	C EMISSION AZIMUTH ANGLE
800	IF ( PX(J) .NE. 0.D0 .OR. PY(J) .NE. 0.D0 ) THEN
801	PHIJ = ATAN2( PY(J), PX(J) )
802	ELSE
803	PHIJ = 0.D0
804	ENDIF
805	CALL ADDANG( COSTHE,PHI, COSTET,PHIJ, SECPAR(3),SECPAR(4) )
806	IF ( SECPAR(3) .LT. C(29) ) THEN
807	C OMIT UPWARD GOING PARTICLES
808	IF (DEBUG) WRITE(MDEBUG,*)'HDPM : ANGLE REJECT PARTICLE ',J
809	GOTO 140
810	ENDIF
811	C PUT SECONDARY PARTICLES ON STACK, IF NOT GOING UPWARDS
812	IF ( J .GT. 2 ) THEN
813	CALL TSTACK
814	ELSE
815	C PUT LEADER OR ANTI-LEADER ON STACK, IF NOT GOING UPWARDS
816	IF ( ITYP(J) .GT. 50 ) THEN
817	C LEADER OR ANTI LEADER ARE RESONANCES AND DECAY
818	IRESPAR = IRESPAR + 1
819	IF ( IRESPAR .GE. 1000 ) THEN
820	WRITE(MONIOU,*) 'STACK OF RESDEC RANDOM NUMBERS FULL'
821	IRESPAR = 999
822	ENDIF
823	RESRAN(IRESPAR) = RDRES(J)
824	C COUNTER FOR ENERGY-MULTIPLICITY MATRIX
825	MSMM = MSMM + 1
826	ENDIF
827	CALL TSTACK
828
829	C CALCULATE ELASTICITY FROM ENERGY OF LEADER (REST OF RESONANCE DECAY)
830	IF ( J. EQ. 1 ) ELASTI = SECPAR(2)*PAMA(NINT(SECPAR(1)))/ELAB
831	ENDIF
832	C COUNTERS FOR FIRST INTERACTION
833	IF ( FIRSTI ) THEN
834	IF ( SECPAR(1) .EQ. 7.D0 .OR. SECPAR(1) .EQ. 8.D0
835	* .OR. SECPAR(1) .EQ. 9.D0 ) THEN
836	IFINPI = IFINPI + 1
837	ELSEIF ( SECPAR(1) .EQ. 13.D0 .OR. SECPAR(1) .EQ. 14.D0
838	* .OR. SECPAR(1) .EQ. 15.D0 .OR. SECPAR(1) .EQ. 25.D0 ) THEN
839	IFINNU = IFINNU + 1
840	ELSEIF ( SECPAR(1) .EQ. 10.D0 .OR. SECPAR(1) .EQ. 11.D0
841	* .OR. SECPAR(1) .EQ. 12.D0 .OR. SECPAR(1) .EQ. 16.D0 ) THEN
842	IFINKA = IFINKA + 1
843	ELSEIF ( SECPAR(1) .GE. 71.D0 .AND. SECPAR(1) .LE. 74.D0) THEN
844	IFINET = IFINET + 1
845	ELSEIF ((SECPAR(1) .GE. 18.D0 .AND. SECPAR(1) .LE. 24.D0)
846	* .OR. (SECPAR(1) .GE. 26.D0 .AND. SECPAR(1) .LE. 32.D0))THEN
847	IFINHY = IFINHY + 1
848	ENDIF
849	ENDIF
850
851	140 CONTINUE
852
853	C COUNTER FOR ENERGY-MULTIPLICITY MATRIX
854	MSMM = MSMM + NTOT - 2
855
856	C FILL ELASTICITY IN MATRICES
857	MEL = MIN ( 1.D0+10.D0* MAX( 0.D0, ELASTI ) , 11.D0 )
858	MEN = MIN ( 4.D0+ 3.D0*LOG10(MAX( .1D0, EKINL )), 37.D0 )
859	IELDPM(MEN,MEL) = IELDPM(MEN,MEL) + 1
860	IELDPA(MEN,MEL) = IELDPA(MEN,MEL) + 1
861	IF ( ELASTI .LT. 1.D0 ) THEN
862	ELMEAN(MEN) = ELMEAN(MEN) + ELASTI
863	ELMEAA(MEN) = ELMEAA(MEN) + ELASTI
864	ENDIF
865
866	IF ( FIRSTI ) THEN
867	ELAST = ELASTI
868	FIRSTI = .FALSE.
869	ENDIF
870
871	IF ( DEBUG ) WRITE(MDEBUG,*) 'HDPM : ELAST=',SNGL(ELASTI),
872	* SNGL(ETOT),SNGL(ELAB)
873
874	RETURN
875	END

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