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decay6.f@ 20115

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Last change on this file since 20115 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.
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1	SUBROUTINE DECAY6(AM0,AM3,AM4,AM5,PARAMA,PARAMB,PARAMC,AMPMX,MODE)
2
3	C-----------------------------------------------------------------------
4	C DECAY (INTO 3 PARTICLES)
5	C
6	C TREATES DECAY INTO 3 PARTICLES; FULLY CONSERVING ENERGY AND MOMENTA
7	C KINEMATIC RANGE PARAMETRISATION SEE PHYS. LETT. 204B (1988) 90-91
8	C FOR LEPTONIC KAON DACAY: THE POLARIZATION OF THE MUON AND
9	C THE NEUTRINO PRODUCTION IS INCLUDED.
10	C THIS SUBROUTINE IS CALLED FROM ETADEC, KDECAY, AND PI0DEC
11	C ARGUMENTS:
12	C AM0 = MASS OF DECAYING PARTICLE
13	C AM3, AM4, AM5 = MASSES OF RESULTING PARTICLES
14	C PARAMA = DALITZ AMPLITUDE PARAMETER (SEE BELOW)
15	C PARAMB = DALITZ AMPLITUDE PARAMETER (SEE BELOW)
16	C PARAMC = DALITZ AMPLITUDE PARAMETER (SEE BELOW)
17	C AMPMX = MAXIMUM AMPLITUDE OF DALITZ PLOT
18	C MODE = 1 FOR DECAY KAON ----> 3 PIONS
19	C = 2 FOR DECAY ETA ----> 3 PIONS OR 2 PIONS + GAMMA
20	C FOR DECAY PI(0) ----> ELECTRON + POSITRON + GAMMA
21	C = 3 FOR DECAY KAON ----> PION + MUON + NEUTRINO
22	C = 4 FOR DECAY KAON ----> PION + ELECTRON + NEUTRINO
23	C
24	C AMPLITUDE PARAMETERS PARAMA, PARAMB, PARAMC ARE DEPENDENT ON MODE:
25	C FOR MODE=1: PARAMA = G DALITZ AMPLITUDE PARAMETRISATION SEE
26	C PARAMB = H PHYS. LETT. 204B (1988) 181 - 193
27	C PARAMC = K
28	C
29	C FOR MODE=2: PARAMA = A DALITZ AMPLITUDE PARAMETRISATION SEE
30	C PARAMB = DUMMY PHYS. LETT. 204B (1988) 173 - 175;
31	C PARAMC = DUMMY J.G. LAYTER ET.AL. PHYS.REV.D7(1973)2565
32	C
33	C FOR MODE>2: PARAMA = LAMBDA-PLUS DALITZ AMPLITUDE PARAMETRISATION
34	C PARAMB = LAMBDA-ZERO SEE PHYS. LETT. 204B (1988)
35	C PARAMC = DUMMY 182 - 194
36	C
37	C DESIGN : D. HECK IK3 FZK KARLSRUHE
38	C-----------------------------------------------------------------------
39
40	IMPLICIT NONE
41	*KEEP,CONST.
42	COMMON /CONST/ PI,PI2,OB3,TB3,ENEPER
43	DOUBLE PRECISION PI,PI2,OB3,TB3,ENEPER
44	*KEEP,DECAY.
45	COMMON /DECAY/ GAM345,COS345,PHI345
46	DOUBLE PRECISION GAM345(3),COS345(3),PHI345(3)
47	*KEEP,PAM.
48	COMMON /PAM/ PAMA,SIGNUM
49	DOUBLE PRECISION PAMA(6000),SIGNUM(6000)
50	*KEEP,PARPAR.
51	COMMON /PARPAR/ CURPAR,SECPAR,PRMPAR,OUTPAR,C,
52	* E00,E00PN,PTOT0,PTOT0N,THICKH,ITYPE,LEVL
53	DOUBLE PRECISION CURPAR(14),SECPAR(14),PRMPAR(14),OUTPAR(14),
54	* C(50),E00,E00PN,PTOT0,PTOT0N,THICKH
55	INTEGER ITYPE,LEVL
56	*KEEP,PARPAE.
57	DOUBLE PRECISION GAMMA,COSTHE,PHI,H,T,X,Y,CHI,BETA,GCM,ECM
58	EQUIVALENCE (CURPAR(2),GAMMA), (CURPAR(3),COSTHE),
59	* (CURPAR(4), PHI ), (CURPAR(5), H ),
60	* (CURPAR(6), T ), (CURPAR(7), X ),
61	* (CURPAR(8), Y ), (CURPAR(9), CHI ),
62	* (CURPAR(10),BETA), (CURPAR(11),GCM ),
63	* (CURPAR(12),ECM )
64	*KEEP,POLAR.
65	COMMON /POLAR/ POLART,POLARF
66	DOUBLE PRECISION POLART,POLARF
67	*KEEP,RANDPA.
68	COMMON /RANDPA/ FAC,U1,U2,RD,NSEQ,ISEED,KNOR
69	DOUBLE PRECISION FAC,U1,U2
70	REAL RD(3000)
71	INTEGER ISEED(103,10),NSEQ
72	LOGICAL KNOR
73	*KEEP,RUNPAR.
74	COMMON /RUNPAR/ FIXHEI,THICK0,HILOECM,HILOELB,
75	* STEPFC,NRRUN,NSHOW,PATAPE,MONIIN,
76	* MONIOU,MDEBUG,NUCNUC,
77	* CETAPE,
78	* SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
79	* N1STTR,MDBASE,
80	* DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
81	* FIX1I,FMUADD,FNKG,FPRINT,FDBASE
82	* ,GHEISH,GHESIG
83	COMMON /RUNPAC/ DSN,HOST,USER
84	DOUBLE PRECISION FIXHEI,THICK0,HILOECM,HILOELB
85	REAL STEPFC
86	INTEGER NRRUN,NSHOW,PATAPE,MONIIN,MONIOU,MDEBUG,NUCNUC,
87	* SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL,
88	* N1STTR,MDBASE
89	INTEGER CETAPE
90	CHARACTER*79 DSN
91	CHARACTER*20 HOST,USER
92
93	LOGICAL DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR,
94	* FIX1I,FMUADD,FNKG,FPRINT,FDBASE
95	* ,GHEISH,GHESIG
96	*KEND.
97
98	DOUBLE PRECISION ABYM,AMPLI,AMPMX,AM0,AM3,AM34I,AM34SQ,AM35SQ,
99	* AM4,AM5,APARAL,APERPN,AUXA,AUXB,AUX1,AUX2,AUX2A,
100	* AUX3,AUX4,AUX4A,AUX5,AUX6,
101	* AUX7,AUX8,AUX10,AUX12,AUX14,BBYM,BOFQ,
102	* CM0SQ,CM3SQ,CM3SQI,CM4SQ,CM5SQ,COSALF,COSBET,
103	* COSFI4,COSOME,COSPHI,COSPSI,COS3CM,COS4CM,COS5CM,
104	* DISCR,EPIPRM,E3CM,E3STAR,E4CM,E5CM,E5STAR,FACT,
105	* GRLAMD,OMEGA,PA,PARAMA,PARAMB,PARAMC,PB,PC,PSI,
106	* P3CM,P3SQ,P4CM,P4SQ,P5CM,P5SQ,ROOT1,ROOT2,
107	* SINALF,SINBET,SINFI4,SINFI5,SINOMG,SINPHI,SINPSI,
108	* SINT4,SINT4I,SINT5I,SIN3CM,S0,TBYMSS,XIT,XI0
109	INTEGER MODE
110	C-----------------------------------------------------------------------
111
112	IF ( DEBUG ) WRITE(MDEBUG,444) AM0,AM3,AM4,AM5
113	444 FORMAT(' DECAY6: AM0',1P,E10.3,' AM3',E10.3,' AM4',E10.3,
114	* ' AM5',E10.3)
115
116	C CALCULATE AUXILIARY QUANTITIES
117	CM0SQ = AM0**2
118	CM3SQ = AM3**2
119	CM4SQ = AM4**2
120	CM5SQ = AM5**2
121	AUX1 = (AM3 + AM4)**2
122	AUX2A = (AM0 - AM5)**2
123	AUX2 = AUX2A - AUX1
124	AUX3 = (AM3 + AM5)**2
125	AUX4A = (AM0 - AM4)**2
126	AUX4 = AUX4A - AUX3
127	AUX5 = CM3SQ - CM4SQ
128	AUX6 = CM0SQ - CM5SQ
129	AUX7 = 0.5D0 / AM0
130	IF ( MODE .EQ. 1 ) THEN
131	AUX8 = (AM0 - AM3)**2
132	S0 = OB3 * ( CM0SQ + CM3SQ + CM4SQ + CM5SQ )
133	AUX10 = 1.D0 / PAMA(8)**2
134	ELSEIF ( MODE .EQ. 2 ) THEN
135	AUX14 = 1.D0 / (AM0 - AM3 - AM4 - AM5)
136	ELSEIF ( MODE .EQ. 3 .OR. MODE .EQ. 4 ) THEN
137	CM3SQI = 1.D0 / CM3SQ
138	AUX12 = (CM0SQ + CM3SQ - CM4SQ) * AUX7
139	C XI0 IS XI(0); GRLAMD IS GREAT LAMBDA
140	XI0 = ( CM0SQ - CM3SQ) * CM3SQI * (PARAMB - PARAMA)
141	GRLAMD = -XI0 * PARAMA
142	ELSE
143	WRITE(MONIOU,*) 'DECAY6: UNEXPECTED MODE =',MODE
144	RETURN
145	ENDIF
146
147	100 CALL RMMAR( RD,3,1 )
148	C ARE INVARIANT MASS SQUARES INSIDE BOUNDARY OF DALITZ PLOT?
149	AM34SQ = AUX2 * RD(1) + AUX1
150	AM35SQ = AUX4 * RD(2) + AUX3
151	AM34I = 0.5D0 / SQRT(AM34SQ)
152	E3STAR = (AUX5 + AM34SQ) * AM34I
153	E5STAR = (AUX6 - AM34SQ) * AM34I
154	ROOT1 = SQRT(E3STAR**2 - CM3SQ )
155	ROOT2 = SQRT(E5STAR**2 - CM5SQ )
156	DISCR = AM35SQ - (E3STAR + E5STAR)**2
157	C REJECT RANDOM NUMBERS, IF OUTSIDE KINEMATIC BOUNDARY OF DALITZ PLOT
158	IF ( DISCR .GT. -(ROOT1 - ROOT2)**2 ) GOTO 100
159	IF ( DISCR .LT. -(ROOT1 + ROOT2)**2 ) GOTO 100
160	C E3CM, E4CM, E5CM ARE ENERGIES IN THE C. M. SYSTEM
161	E4CM = (CM0SQ + CM4SQ - AM35SQ) * AUX7
162	E5CM = (CM0SQ + CM5SQ - AM34SQ) * AUX7
163	E3CM = AM0 - E4CM - E5CM
164
165	IF ( MODE .EQ. 1 ) THEN
166	FACT = AUX10 * (AUX2A - 2.D0AM0(E5CM-AM5) - S0)
167	C AMPLITUDE OF SQUARED MATRIX ELEMENT (SEE PHYS. LETT. B204 (1988) 181)
168	AMPLI = 1.D0 + PARAMAFACT + PARAMBFACT*2 + PARAMC( AUX10
169	* * ( AUX4A -AUX8 -2.D0(E4CM-AM4-E3CM+AM3)AM0 ) )**2
170
171	ELSEIF ( MODE .EQ. 2 ) THEN
172	C AMPLITUDE OF SQUARED MATRIX ELEMENT (SEE PHYS. LETT. B204 (1988) 173)
173	C REF: J. G. LAYTER ET AL., PHYS. REV. D7 (1973) 2565
174	AMPLI = 1.D0 + PARAMA * ( 3.D0 * (E5CM - AM5) * AUX14 - 1.D0 )
175
176	ELSE
177	C EPIPRM IS (ENERGY OF PION)PRIMED
178	EPIPRM = AUX12 - E3CM
179	C PA, PB, AND PC ARE THE A, B, AND C PARAMETERS
180	PA = AM0 * ( 2.D0 * E4CM * E5CM - AM0 * EPIPRM )
181	* + CM4SQ * ( 0.25D0 * EPIPRM - E5CM )
182	PB = CM4SQ * ( E5CM - 0.5D0 * EPIPRM )
183	PC = CM4SQ * EPIPRM * 0.25D0
184	C TBYMSS IS T DIVIDED BY MASS SQUARE OF PION
185	TBYMSS = (CM0SQ + CM3SQ - 2.D0 * AM0 * E3CM) * CM3SQI
186	C XIT IS XI(T)
187	XIT = XI0 + GRLAMD*TBYMSS
188	C AMPLITUDE OF SQUARED MATRIX ELEMENT (PHYS. LETT. B204 (1988) 183)
189	AMPLI = (1.D0 + PARAMATBYMSS)2 ( PA + XITPB + XIT2 PC )
190	ENDIF
191
192	C REJECT RANDOM NUMBERS, IF RD(3) IS LARGER THAN DALITZ PLOT AMPLITUDE
193	IF ( RD(3)*AMPMX .GT. AMPLI ) GOTO 100
194
195	IF (DEBUG) WRITE(MDEBUG,*)'DECAY6: E3CM,E4CM,E5CM=',
196	* SNGL(E3CM),SNGL(E4CM),SNGL(E5CM)
197	C P3CM, P4CM, P5CM ARE MOMENTA IN THE C.M. SYSTEM
198	C P3SQ, P4SQ, P5SQ ARE SQUARED MOMENTA IN C.M. SYSTEM
199	P5SQ = E5CM**2 - CM5SQ
200	P5CM = SQRT(P5SQ)
201	P4SQ = E4CM**2 - CM4SQ
202	P4CM = SQRT(P4SQ)
203	P3SQ = E3CM**2 - CM3SQ
204	P3CM = SQRT(P3SQ)
205	C ANGLE ALFA AND BETA ARE BETWEEN PARTICLE 3 AND 4 RSP. 3 AND 5
206	COSALF = (P5SQ - P3SQ - P4SQ) / (2.D0 * P3CM * P4CM)
207	SINALF = -SQRT(1.D0 - COSALF**2)
208	COSBET = (P4SQ - P3SQ - P5SQ) / (2.D0 * P3CM * P5CM)
209	SINBET = SQRT(1.D0 - COSBET**2)
210	C NOW SELECT RANDOM NUMBERS FOR THREE INDEPENDENT ANGLES IN CM-SYSTEM
211	C COS3CM AND PHI ARE ANGLES OF PARTICLE 3 RELATIVE TO DECAYING PARTICLE
212	CALL RMMAR( RD,3,1 )
213	COS3CM = 2.D0*RD(1) - 1.D0
214	SIN3CM = SQRT(1.D0 - COS3CM**2)
215	PHI345(1) = PI2 * RD(2)
216	COSPHI = COS( PHI345(1) )
217	SINPHI = SIN( PHI345(1) )
218	C ANGLE PSI GIVES ROTATION OF PLANE (3,4,5) RELATIVE TO PLANE (1,3)
219	PSI = PI2 * RD(3)
220	COSPSI = COS(PSI)
221	SINPSI = SIN(PSI)
222	C CALCULATE ALL NEEDED POLAR AND AZIMUTHAL ANGLES IN THE CM-SYSTEM
223	COS4CM = COS3CM * COSALF - SIN3CM * COSPSI * SINALF
224	IF ( ABS(COS4CM) .LT. 1.D0 ) THEN
225	SINT4 = SQRT(1.D0 - COS4CM**2)
226	SINT4I = 1.D0 / SINT4
227	AUXA = COS3CM * COSPSI * SINALF + SIN3CM * COSALF
228	COSFI4 = (COSPHIAUXA-SINPHISINPSISINALF) SINT4I
229	PHI345(2) = ACOS( MAX( -1.D0, MIN( 1.D0, COSFI4 ) ) )
230	SINFI4 = (SINPHIAUXA+COSPHISINPSISINALF) SINT4I
231	IF ( SINFI4 .LE. 0.D0 ) PHI345(2) = PI2 - PHI345(2)
232	ELSE
233	PHI345(2) = 0.D0
234	ENDIF
235	C CALCULATE GAMMA FACTORS AND POLAR ANGLES IN LABORATORY SYSTEM
236	GAM345(1) = GAMMA * (E3CM + BETA * P3CM * COS3CM) / AM3
237	COS345(1) = MIN( 1.D0, (BETA * E3CM + P3CM * COS3CM) * GAMMA
238	* / ( AM3 * SQRT(GAM345(1)**2 - 1.D0) ) )
239	GAM345(2) = GAMMA * (E4CM + BETA * P4CM * COS4CM) / AM4
240	COS345(2) = MIN( 1.D0, (BETA * E4CM + P4CM * COS4CM) * GAMMA
241	* / ( AM4 * SQRT(GAM345(2)**2 - 1.D0) ) )
242	C CALCULATE PARAMETERS OF PARTICLE 5, IF NEEDED
243	IF ( MODE .LE. 2 ) THEN
244	COS5CM = COS3CM * COSBET - SIN3CM * COSPSI * SINBET
245	IF ( ABS(COS5CM) .LT. 1.D0 ) THEN
246	SINT5I = 1.D0 / SQRT(1.D0 - COS5CM**2)
247	AUXB = COS3CM * COSPSI * SINBET + SIN3CM * COSBET
248	PHI345(3) = ACOS((COSPHIAUXB-SINPHISINPSISINBET) SINT5I)
249	SINFI5 = (SINPHIAUXB+COSPHISINPSISINBET) SINT5I
250	IF ( SINFI5 .LE. 0.D0 ) PHI345(3) = PI2 - PHI345(3)
251	ELSE
252	PHI345(3) = 0.D0
253	ENDIF
254	IF ( AM5 .NE. 0.D0 ) THEN
255	GAM345(3) = GAMMA * (E5CM + BETA * P5CM * COS5CM) / AM5
256	COS345(3) = MIN( 1.D0, (BETA * E5CM + P5CM * COS5CM) * GAMMA
257	* / ( AM5 * SQRT(GAM345(3)**2 - 1.D0) ) )
258	ELSE
259	C IF PARTICLE 5 IS GAMMA RAY OR NEUTRINO, THEN GAM345(3) IS THE ENERGY
260	GAM345(3) = GAMMA * (E5CM + BETA * P5CM * COS5CM)
261	COS345(3) = MIN( 1.D0, (BETA * E5CM + P5CM * COS5CM) * GAMMA
262	* / GAM345(3) )
263	ENDIF
264	ENDIF
265
266	IF ( MODE .EQ. 3 ) THEN
267	C CALCULATION OF MUON POLARIZATION. WE FOLLOW THE DESCRIPTION OF
268	C L. JAUNEAU, IN: METHODS IN SUBNUCLEAR PHYSICS, VOL. 3, M. NIKOLIC ED.
269	C (GORDON + BREACH, NEW YORK, 1969), P. 123
270	C SEE ALSO: L.M. CHOUNET ET AL., PHYS. REP. 4 (1972) 199, APPENDIX 1.
271	C SEE ALSO: N. CABBIBO, A. MAKSYMOWICZ, PHYS. LETT. 9 (1964) 352
272	C (CORRECTIONS IN: PHYS. LETT. 11 (1964) 360; 14 (1965) 72)
273	C WE DEFINE BOFQ (READ: B OF Q), WHICH IS -B(Q*2)4
274	BOFQ = 1.D0 - XIT
275	C ABYM AND BBYM (READ A BY M; B BY M) ARE THE QUANTITIES A/M AND B/M
276	ABYM = AM0 * ( BOFQ * EPIPRM - 2.D0 * E5CM )
277	BBYM = CM0SQ + 0.25D0 * CM4SQ * BOFQ*2 - BOFQ AM0 * E4CM
278	C NOW CALCULATE THE COMPONENTS APARAL (PARALLEL TO MU DIRECTION) AND
279	C APERPN (PERPENDICULAR TO MU DIRECTION) USING QUANTITIES DEFINED IN
280	C KAON REST SYSTEM. NOTE OUR DEFINITION OF SINALF (ALWAYS WITH NEGATIVE
281	C SIGN) OPPOSITE TO CABBIBO'S SIN(PSI) AND JAUNEAU'S SIN(THETA)
282	APARAL = -P3CMAM4BBYMCOSALF - P4CM ( AM0ABYM - BBYM
283	* ( P3CMSINALF(E4CM-AM4)/P4CM + AM0 - E3CM ) )
284	APERPN = P3CMAM4BBYM*SINALF
285	C NOW NORMALIZE THE PARALLEL COMPONENT OF POLARIZATION; POLART IS
286	C COSINE OF THE ANGLE BETWEEN MUON MOMENTUM AND POLARISATION
287	POLART = APARAL / SQRT(APARAL2 + APERPN2)
288	C THE POLARIZATION VECTOR LIES IN THE PLANE OF MOMENTA (PION,MUON).
289	C OMEGA IS THE ANGLE BY WHICH THE DECAY PLANE (PION,MUON) IS ROTATET
290	C AROUND THE DIRECTION OF MUON RELATIVE TO THE PLANE (KAON,MUON)
291	IF ( ABS(COS4CM) .LT. 1.D0 .AND. SINALF .NE. 0.D0 ) THEN
292	COSOME = (COS4CMCOSALF - COS3CM)SINT4I/SINALF
293	OMEGA = ACOS( MAX( -1.D0, MIN( 1.D0, COSOME ) ) )
294	IF ( SINFI4 .NE. 0.D0 ) THEN
295	SINOMG = ( COSFI4 * ( COSALF - COS3CMCOS4CM ) SINT4I
296	* - SIN3CM * COSPHI ) / (SINALF*SINFI4)
297	IF ( SINOMG .LT. 0.D0 ) OMEGA = PI2 - OMEGA
298	ENDIF
299	ELSE
300	OMEGA = 0.D0
301	ENDIF
302	POLARF = OMEGA
303	ENDIF
304
305	RETURN
306	END

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