gpamela/gptrd/gpxtr.F

*
* $Id: gpxtr.F,v 3.1.1.1 2002/07/11 16:02:01 cafagna Exp $
*
* $Log: gpxtr.F,v $
* Revision 3.1.1.1  2002/07/11 16:02:01  cafagna
* First GPAMELA release on CVS
*
*
*CMZ :  3.00/00 05/02/2002  12.51.38  by  Unknown
*-- Author :    Marialuigia Ambriola   11/05/2001
      SUBROUTINE GPXTR
**************************************************************************
*                                                                        *
*       Generates and absorbs transition radiatixon spectrum in TRD       *
*                                                                        *
*                                                                        *
*                                                                        *
* Called by: GUSTEP                                                      *
* Author:  Marialuigia Ambriola   11/05/2001                             *
*                                                                        *
**************************************************************************
#include "gpgene.inc"
#include "gctrak.inc"
#include "gctmed.inc"
#include "gpmed.inc"
#include "gpsed.inc"
#include "gcsets.inc"
#include "gpaltr.inc"
#include "gckine.inc"
#include "gcnum.inc"
#include "gcflag.inc"
#include "gptotr.inc"
#include "gcunit.inc"
        EXTERNAL XTRYIELD
        EXTERNAL NPOISS
        EXTERNAL XTRINTER
        EXTERNAL XTRINTEG
        REAL CAM,RL,G,NF,WR,CR,SPH,CATT,W,E
        REAL GRNDM0(1)
        INTEGER INDEX,INDEXAIR,INDEXC,LAY
c centimeter and GeV:
        DATA RL1/7.0E-4/,RL2/204.E-4/,N/71/,w1/31.59E-9/,w2/.7E-9/
        DATA IEVOLD/-1/,NTMOLD/-1/
        PARAMETER (ALPHA=1/137.,PG=3.1415926536,HTC=197.3269E-16)
        PARAMETER (C=3.E+10)
**************
*particle inside kapton, radiator or xenon?
*if yes, calcolates the length of the track.
*NUMED is the number of the tracking medium (common GCTMED)
*MTRAD, MKAP and MXE are the numbers of radiator, kapton and xenon
*tracking media, like defined by GPAMELA.
        IF(CHARGE.EQ.0) THEN
           RETURN
        ENDIF
        IF(AMASS.LE.0) THEN
           WRITE(CHMAIL,10000) AMASS
           CALL GMAIL(1,0)
           RETURN
        ENDIF
        G=GETOT/AMASS
        IF(G.LE.100.) THEN
           RETURN
        ENDIF
          IF((NUMED.EQ.MKAP.AND.IDET.EQ.IDTRSO).OR.NUMED.EQ.
     +       MTRAD.OR.NUMED.EQ.MXE) THEN
           IF(INWVOL.EQ.1.) THEN
             CAM=SLENG
             RETURN
           ELSEIF(INWVOL.EQ.2) THEN
C #
C # Calculate the layer number
C #
              IF(NUMED.EQ.MXE) THEN
               IF(NUMBV(NVNAME-1).GE.29.AND.NUMBV(NVNAME-1).LE.32)LAY=2
               IF(NUMBV(NVNAME-1).GE.25.AND.NUMBV(NVNAME-1).LE.28)LAY=4
               IF(NUMBV(NVNAME-1).GE.21.AND.NUMBV(NVNAME-1).LE.24)LAY=6
               IF(NUMBV(NVNAME-1).GE.17.AND.NUMBV(NVNAME-1).LE.20)LAY=8
               IF(NUMBV(NVNAME-1).GE.13.AND.NUMBV(NVNAME-1).LE.16)LAY=10
               IF(NUMBV(NVNAME-1).GE.10.AND.NUMBV(NVNAME-1).LE.12)LAY=12
               IF(NUMBV(NVNAME-1).GE.7.AND.NUMBV(NVNAME-1).LE.9)LAY=14
               IF(NUMBV(NVNAME-1).GE.4.AND.NUMBV(NVNAME-1).LE.6)LAY=16
               IF(NUMBV(NVNAME-1).GE.1.AND.NUMBV(NVNAME-1).LE.3)LAY=18
               IF(NUMBV(NVNAME).GT.16) THEN
                  LAY = LAY - 1
               ENDIF
              ENDIF
             CAM=SLENG-CAM
           ELSE
             RETURN
           ENDIF
          ELSE
           RETURN
          ENDIF
****************
          INDEX=0
          INDEXAIR=0
          INDEXC=0
          IF(INWVOL.NE.2) RETURN
          IF(IEVOLD.NE.IEVENT.OR.NTMOLD.NE.NTMULT) THEN
             CALL VZERO(EY,115)
          ENDIF
          IEVOLD=IEVENT
          NTMOLD=NTMULT
          SPH=0.
          NPHTR=0
          ENPHTR=0.
          IF(NUMED.EQ.MKAP.AND.IDET.EQ.IDTRSO) INDEX=4
          IF(NUMED.EQ.MXE) INDEX=3
          IF(NUMED.EQ.MTRAD) THEN
             INDEXAIR=1
             INDEXC=2
             RL=RL1+RL2
          ENDIF
****************
c radiator:
          IF(INDEX.EQ.0) THEN
             NF=CAM/RL
             DO I=1,115
              XTREN=XTRYIELD(I,G)
              WR=0.
              CR=NF*(ATTTRD(I,INDEXAIR)*RL2+ATTTRD(I,INDEXC)*RL1)
              IF(CR.GT.0.) WR=EXP(-CR)
c considering the whole radiator and the absorption.
c when dividing for enatt I consider the number of photons per unit energy,
c which are created and transmitted by the radiator.
C remember that enatt is in keV unity.
              IF(CR.GT.0.AND.NF.GT.1) THEN
                 XTREN=2*NF*XTREN*(1.-WR)/(CR*ENATT(I))
                 EY(I)=EY(I)*WR+XTREN
                 SPH=SPH+EY(I)
              ENDIF
             ENDDO
          ENDIF
          goto 999
          print*,'index,IEVENT,gamma,spettro'
          print*,index,IEVENT,g
          print*,(ey(i),i=1,4)
          print*,(ey(i),i=5,8)
          print*,(ey(i),i=9,12)
          print*,(ey(i),i=13,16)
          print*,(ey(i),i=17,20)
          print*,(ey(i),i=21,24)
          print*,(ey(i),i=25,28)
          print*,(ey(i),i=29,32)
          print*,(ey(i),i=33,36)
          print*,(ey(i),i=37,40)
          print*,(ey(i),i=41,44)
          print*,(ey(i),i=45,48)
          print*,(ey(i),i=49,52)
          print*,(ey(i),i=53,56)
          print*,(ey(i),i=57,60)
          print*,(ey(i),i=61,64)
          print*,(ey(i),i=65,68)
          print*,(ey(i),i=69,72)
          print*,(ey(i),i=73,76)
          print*,(ey(i),i=77,80)
          print*,(ey(i),i=81,84)
          print*,(ey(i),i=85,88)
          print*,(ey(i),i=89,92)
          print*,(ey(i),i=93,96)
          print*,(ey(i),i=97,100)
          print*,(ey(i),i=101,104)
          print*,(ey(i),i=105,108)
          print*,(ey(i),i=109,112)
          print*,(ey(i),i=113,115)
 999      continue
******************
C now the spectrum is propagated in the other absorbent media in the TRD:
c the absorber could be the kapton or the Xe-CO2 or the gas in between (here
c not considered):
          IF(INDEX.NE.0) THEN
             CALL VZERO(EA,115)
             CALL VZERO(ER,115)
             DO I=1,115
                CATT=ATTTRD(I,INDEX)*CAM
                W=0
                W=EXP(-CATT)
C               PRINT*,'EY(I),I,CATT,ATT',EY(I),I,CATT,ATTTRD(I,INDEX)
c absorbed spectrum:
                EA(I)=EY(I)*(1-W)
c transmitted spectrum:
                EY(I)=EY(I)*W
C               PRINT*,'W,EA(I),EY(I),I,INDEX',W,EA(I),EY(I),I,INDEX
             ENDDO
          ENDIF
C finally the sensitive gas:
          IF(INDEX.EQ.3) THEN
             goto 998
             print*,'index,IEVENT,gamma,spettro assorbito'
             print*,index,IEVENT,g
             print*,(ea(i),i=1,4)
             print*,(ea(i),i=5,8)
             print*,(ea(i),i=9,12)
             print*,(ea(i),i=13,16)
             print*,(ea(i),i=17,20)
             print*,(ea(i),i=21,24)
             print*,(ea(i),i=25,28)
             print*,(ea(i),i=29,32)
             print*,(ea(i),i=33,36)
             print*,(ea(i),i=37,40)
             print*,(ea(i),i=41,44)
             print*,(ea(i),i=45,48)
             print*,(ea(i),i=49,52)
             print*,(ea(i),i=53,56)
             print*,(ea(i),i=57,60)
             print*,(ea(i),i=61,64)
             print*,(ea(i),i=65,68)
             print*,(ea(i),i=69,72)
             print*,(ea(i),i=73,76)
             print*,(ea(i),i=77,80)
             print*,(ea(i),i=81,84)
             print*,(ea(i),i=85,88)
             print*,(ea(i),i=89,92)
             print*,(ea(i),i=93,96)
             print*,(ea(i),i=97,100)
             print*,(ea(i),i=101,104)
             print*,(ea(i),i=105,108)
             print*,(ea(i),i=109,112)
             print*,(ea(i),i=113,115)
 998         continue
c considering the escape peak in Xe-CO2;
             CALL XESCAPE(ENATT,EA,ER,115)
             SPH=0.
             goto 997
             print*,'index,IEVENT,gamma,spettro con escape'
             print*,index,IEVENT,g
             print*,(er(i),i=1,4)
             print*,(er(i),i=5,8)
             print*,(er(i),i=9,12)
             print*,(er(i),i=13,16)
             print*,(er(i),i=17,20)
             print*,(er(i),i=21,24)
             print*,(er(i),i=25,28)
             print*,(er(i),i=29,32)
             print*,(er(i),i=33,36)
             print*,(er(i),i=37,40)
             print*,(er(i),i=41,44)
             print*,(er(i),i=45,48)
             print*,(er(i),i=49,52)
             print*,(er(i),i=53,56)
             print*,(er(i),i=57,60)
             print*,(er(i),i=61,64)
             print*,(er(i),i=65,68)
             print*,(er(i),i=69,72)
             print*,(er(i),i=73,76)
             print*,(er(i),i=77,80)
             print*,(er(i),i=81,84)
             print*,(er(i),i=85,88)
             print*,(er(i),i=89,92)
             print*,(er(i),i=93,96)
             print*,(er(i),i=97,100)
             print*,(er(i),i=101,104)
             print*,(er(i),i=105,108)
             print*,(er(i),i=109,112)
             print*,(er(i),i=113,115)
 997         continue
c yes escape peak:
ccc             SPH=XTRINTEG(ENATT,ER,EINT,115)
             SPH=XTRINTEG(ENATT,ER,EINT,75)
c if you don't consider the escape-peak, don't comment the next row:
C              SPH=XTRINTEG(ENATT,EA,EINT,115)
C 28/9/2001: FINE TUNING OF TR:
c for PS ALFA=0.65 (momentum.lt.40. GeV/c)
c per SPS ALFA=0.69 (momentum.ge.40. GeV/c):
             IF(ALFATR.NE.-9999.) THEN
                SPH=ALFATR*SPH
             ELSE
                TROK=.FALSE.
                WRITE(CHMAIL,10100) ALFATR
                CALL GMAIL(1,0)
                RETURN
             ENDIF
c end 28/9/2001.
             NPHTR=NPOISS(SPH)
c             print*,'lay=',lay,'sph,nph=',sph,nph
c             PRINT*,'Xe-CO2: XTRINTEG,NPOISS:',SPH,NPHTR
             IF(NPHTR.GT.0) THEN
                DO I=1,NPHTR
ccc 10                E=XTRINTER(RNDM(1)*SPH,EINT,ENATT,115)
c ml 26/03/04
c 10                E=XTRINTER(RNDM(1)*SPH,EINT,ENATT,75)
 10                CALL GRNDM(GRNDM0,1)
                   E=XTRINTER(GRNDM0(1)*SPH,EINT,ENATT,75)
C ml 26/03/04
C 28/9/2001: TENTATIVO DI FINE TUNING DELLA TR:
******** NEI DATI REALI NON VEDO FOTONI CON ENERGIA MAGGIORE DI 60 keV:
c fine modifica 28/9/2001
                   IF(E.GT.45.) THEN
                      PRINT*,'Extracted energy'
                      PRINT*,E
                      GOTO 10
                   ENDIF
                   ENPHTR=ENPHTR+E
                ENDDO
c                PRINT*,'Energy (keV) and photons absorbed, for event:'
c     +               ,IEVENT,ENPHTR,NPHTR ,'layer=',lay
C               NTRHIT=NPHTR
C               ENEHIT=ENPHTR*1.E-6
C* ML: SOTTRAE LA ENERGIA PERSA NEL TRD.
                GEKINT=GEKIN-ENPHTR*1.E-6
                GEKIN=GEKINT
                GETOT=GEKIN +AMASS
                VECT(7)= SQRT((GETOT+AMASS)*GEKIN)
C Routine to find bin number in kinetic energy table stored in ELOW(NEKBIN)
                CALL GEKBIN
C* END ML.
             ELSE
c                PRINT*,'no photons converted in the straw'
             ENDIF
             IF (LAY.GT.0.AND.LAY.LE.18) THEN
                ENTRTOT = ENTRTOT + ENPHTR
                ENLAY(LAY) = ENLAY(LAY) + ENPHTR
                NPHTOTR = NPHTOTR + NPHTR
                NPHLAY(LAY)= NPHLAY(LAY) + NPHTR
                ILI=NUMBV(NVNAME-1)
                IHI=NUMBV(NVNAME)
                ENTRSTRAW(ILI,IHI) = ENTRSTRAW(ILI,IHI)+ ENPHTR
                NTRSTRAW(ILI,IHI) = NTRSTRAW(ILI,IHI)+ NPHTR
c                PRINT*,'NPHTOTR,LAY,ENPHTR,ENTRTOT',NPHTOTR,LAY,ENPHTR,ENTRTOT
C                PRINT*,'NTRSTRAW',NTRSTRAW(ILI,IHI),ILI,IHI
C                PRINT*,'ENTRSTRAW,ENPHTR',ENTRSTRAW(ILI,IHI),ENPHTR
             ELSE
                WRITE(CHMAIL,10200)LAY
                CALL GMAIL(1,0)
C                PRINT*,' ERROR IN LAYER CALCULATION',LAY
             ENDIF
          ENDIF
10000     FORMAT('GPXTR error: negative mass =',F10.3)
10100     FORMAT('GPXTR error: ALFATR not set, TR process ',
     +  'and his tuning will be ignored, ALFATR =',F10.3)
10200     FORMAT('GPXTR error in layer calculation =',F10.3)
          RETURN
          END
1	cafagna	3.1	*
2	pamela	3.2	* $Id: gpxtr.F,v 3.1.1.1 2002/07/11 16:02:01 cafagna Exp $
3			*
4			* $Log: gpxtr.F,v $
5			* Revision 3.1.1.1 2002/07/11 16:02:01 cafagna
6			* First GPAMELA release on CVS
7	cafagna	3.1	*
8			*
9			*CMZ : 3.00/00 05/02/2002 12.51.38 by Unknown
10			*-- Author : Marialuigia Ambriola 11/05/2001
11			SUBROUTINE GPXTR
12			**************************************************************************
13			* *
14	pamela	3.2	* Generates and absorbs transition radiatixon spectrum in TRD *
15	cafagna	3.1	* *
16			* *
17			* *
18			* Called by: GUSTEP *
19			* Author: Marialuigia Ambriola 11/05/2001 *
20			* *
21			**************************************************************************
22			#include "gpgene.inc"
23			#include "gctrak.inc"
24			#include "gctmed.inc"
25			#include "gpmed.inc"
26			#include "gpsed.inc"
27			#include "gcsets.inc"
28			#include "gpaltr.inc"
29			#include "gckine.inc"
30			#include "gcnum.inc"
31			#include "gcflag.inc"
32			#include "gptotr.inc"
33			#include "gcunit.inc"
34			EXTERNAL XTRYIELD
35			EXTERNAL NPOISS
36			EXTERNAL XTRINTER
37			EXTERNAL XTRINTEG
38			REAL CAM,RL,G,NF,WR,CR,SPH,CATT,W,E
39	pamela	3.2	REAL GRNDM0(1)
40	cafagna	3.1	INTEGER INDEX,INDEXAIR,INDEXC,LAY
41			c centimeter and GeV:
42			DATA RL1/7.0E-4/,RL2/204.E-4/,N/71/,w1/31.59E-9/,w2/.7E-9/
43			DATA IEVOLD/-1/,NTMOLD/-1/
44			PARAMETER (ALPHA=1/137.,PG=3.1415926536,HTC=197.3269E-16)
45			PARAMETER (C=3.E+10)
46			**************
47			*particle inside kapton, radiator or xenon?
48			*if yes, calcolates the length of the track.
49			*NUMED is the number of the tracking medium (common GCTMED)
50			*MTRAD, MKAP and MXE are the numbers of radiator, kapton and xenon
51			*tracking media, like defined by GPAMELA.
52			IF(CHARGE.EQ.0) THEN
53			RETURN
54			ENDIF
55			IF(AMASS.LE.0) THEN
56			WRITE(CHMAIL,10000) AMASS
57			CALL GMAIL(1,0)
58			RETURN
59			ENDIF
60			G=GETOT/AMASS
61			IF(G.LE.100.) THEN
62			RETURN
63			ENDIF
64			IF((NUMED.EQ.MKAP.AND.IDET.EQ.IDTRSO).OR.NUMED.EQ.
65			+ MTRAD.OR.NUMED.EQ.MXE) THEN
66			IF(INWVOL.EQ.1.) THEN
67			CAM=SLENG
68			RETURN
69			ELSEIF(INWVOL.EQ.2) THEN
70			C #
71			C # Calculate the layer number
72			C #
73			IF(NUMED.EQ.MXE) THEN
74			IF(NUMBV(NVNAME-1).GE.29.AND.NUMBV(NVNAME-1).LE.32)LAY=2
75			IF(NUMBV(NVNAME-1).GE.25.AND.NUMBV(NVNAME-1).LE.28)LAY=4
76			IF(NUMBV(NVNAME-1).GE.21.AND.NUMBV(NVNAME-1).LE.24)LAY=6
77			IF(NUMBV(NVNAME-1).GE.17.AND.NUMBV(NVNAME-1).LE.20)LAY=8
78			IF(NUMBV(NVNAME-1).GE.13.AND.NUMBV(NVNAME-1).LE.16)LAY=10
79			IF(NUMBV(NVNAME-1).GE.10.AND.NUMBV(NVNAME-1).LE.12)LAY=12
80			IF(NUMBV(NVNAME-1).GE.7.AND.NUMBV(NVNAME-1).LE.9)LAY=14
81			IF(NUMBV(NVNAME-1).GE.4.AND.NUMBV(NVNAME-1).LE.6)LAY=16
82			IF(NUMBV(NVNAME-1).GE.1.AND.NUMBV(NVNAME-1).LE.3)LAY=18
83			IF(NUMBV(NVNAME).GT.16) THEN
84			LAY = LAY - 1
85			ENDIF
86			ENDIF
87			CAM=SLENG-CAM
88			ELSE
89			RETURN
90			ENDIF
91			ELSE
92			RETURN
93			ENDIF
94			****************
95			INDEX=0
96			INDEXAIR=0
97			INDEXC=0
98			IF(INWVOL.NE.2) RETURN
99			IF(IEVOLD.NE.IEVENT.OR.NTMOLD.NE.NTMULT) THEN
100			CALL VZERO(EY,115)
101			ENDIF
102			IEVOLD=IEVENT
103			NTMOLD=NTMULT
104			SPH=0.
105			NPHTR=0
106			ENPHTR=0.
107			IF(NUMED.EQ.MKAP.AND.IDET.EQ.IDTRSO) INDEX=4
108			IF(NUMED.EQ.MXE) INDEX=3
109			IF(NUMED.EQ.MTRAD) THEN
110			INDEXAIR=1
111			INDEXC=2
112			RL=RL1+RL2
113			ENDIF
114			****************
115			c radiator:
116			IF(INDEX.EQ.0) THEN
117			NF=CAM/RL
118			DO I=1,115
119			XTREN=XTRYIELD(I,G)
120			WR=0.
121			CR=NF(ATTTRD(I,INDEXAIR)RL2+ATTTRD(I,INDEXC)*RL1)
122			IF(CR.GT.0.) WR=EXP(-CR)
123			c considering the whole radiator and the absorption.
124			c when dividing for enatt I consider the number of photons per unit energy,
125			c which are created and transmitted by the radiator.
126			C remember that enatt is in keV unity.
127			IF(CR.GT.0.AND.NF.GT.1) THEN
128			XTREN=2NFXTREN(1.-WR)/(CRENATT(I))
129			EY(I)=EY(I)*WR+XTREN
130			SPH=SPH+EY(I)
131			ENDIF
132			ENDDO
133			ENDIF
134			goto 999
135			print*,'index,IEVENT,gamma,spettro'
136			print*,index,IEVENT,g
137			print*,(ey(i),i=1,4)
138			print*,(ey(i),i=5,8)
139			print*,(ey(i),i=9,12)
140			print*,(ey(i),i=13,16)
141			print*,(ey(i),i=17,20)
142			print*,(ey(i),i=21,24)
143			print*,(ey(i),i=25,28)
144			print*,(ey(i),i=29,32)
145			print*,(ey(i),i=33,36)
146			print*,(ey(i),i=37,40)
147			print*,(ey(i),i=41,44)
148			print*,(ey(i),i=45,48)
149			print*,(ey(i),i=49,52)
150			print*,(ey(i),i=53,56)
151			print*,(ey(i),i=57,60)
152			print*,(ey(i),i=61,64)
153			print*,(ey(i),i=65,68)
154			print*,(ey(i),i=69,72)
155			print*,(ey(i),i=73,76)
156			print*,(ey(i),i=77,80)
157			print*,(ey(i),i=81,84)
158			print*,(ey(i),i=85,88)
159			print*,(ey(i),i=89,92)
160			print*,(ey(i),i=93,96)
161			print*,(ey(i),i=97,100)
162			print*,(ey(i),i=101,104)
163			print*,(ey(i),i=105,108)
164			print*,(ey(i),i=109,112)
165			print*,(ey(i),i=113,115)
166			999 continue
167			******************
168			C now the spectrum is propagated in the other absorbent media in the TRD:
169			c the absorber could be the kapton or the Xe-CO2 or the gas in between (here
170			c not considered):
171			IF(INDEX.NE.0) THEN
172			CALL VZERO(EA,115)
173			CALL VZERO(ER,115)
174			DO I=1,115
175			CATT=ATTTRD(I,INDEX)*CAM
176			W=0
177			W=EXP(-CATT)
178			C PRINT*,'EY(I),I,CATT,ATT',EY(I),I,CATT,ATTTRD(I,INDEX)
179			c absorbed spectrum:
180			EA(I)=EY(I)*(1-W)
181			c transmitted spectrum:
182			EY(I)=EY(I)*W
183			C PRINT*,'W,EA(I),EY(I),I,INDEX',W,EA(I),EY(I),I,INDEX
184			ENDDO
185			ENDIF
186			C finally the sensitive gas:
187			IF(INDEX.EQ.3) THEN
188			goto 998
189			print*,'index,IEVENT,gamma,spettro assorbito'
190			print*,index,IEVENT,g
191			print*,(ea(i),i=1,4)
192			print*,(ea(i),i=5,8)
193			print*,(ea(i),i=9,12)
194			print*,(ea(i),i=13,16)
195			print*,(ea(i),i=17,20)
196			print*,(ea(i),i=21,24)
197			print*,(ea(i),i=25,28)
198			print*,(ea(i),i=29,32)
199			print*,(ea(i),i=33,36)
200			print*,(ea(i),i=37,40)
201			print*,(ea(i),i=41,44)
202			print*,(ea(i),i=45,48)
203			print*,(ea(i),i=49,52)
204			print*,(ea(i),i=53,56)
205			print*,(ea(i),i=57,60)
206			print*,(ea(i),i=61,64)
207			print*,(ea(i),i=65,68)
208			print*,(ea(i),i=69,72)
209			print*,(ea(i),i=73,76)
210			print*,(ea(i),i=77,80)
211			print*,(ea(i),i=81,84)
212			print*,(ea(i),i=85,88)
213			print*,(ea(i),i=89,92)
214			print*,(ea(i),i=93,96)
215			print*,(ea(i),i=97,100)
216			print*,(ea(i),i=101,104)
217			print*,(ea(i),i=105,108)
218			print*,(ea(i),i=109,112)
219			print*,(ea(i),i=113,115)
220			998 continue
221			c considering the escape peak in Xe-CO2;
222			CALL XESCAPE(ENATT,EA,ER,115)
223			SPH=0.
224			goto 997
225			print*,'index,IEVENT,gamma,spettro con escape'
226			print*,index,IEVENT,g
227			print*,(er(i),i=1,4)
228			print*,(er(i),i=5,8)
229			print*,(er(i),i=9,12)
230			print*,(er(i),i=13,16)
231			print*,(er(i),i=17,20)
232			print*,(er(i),i=21,24)
233			print*,(er(i),i=25,28)
234			print*,(er(i),i=29,32)
235			print*,(er(i),i=33,36)
236			print*,(er(i),i=37,40)
237			print*,(er(i),i=41,44)
238			print*,(er(i),i=45,48)
239			print*,(er(i),i=49,52)
240			print*,(er(i),i=53,56)
241			print*,(er(i),i=57,60)
242			print*,(er(i),i=61,64)
243			print*,(er(i),i=65,68)
244			print*,(er(i),i=69,72)
245			print*,(er(i),i=73,76)
246			print*,(er(i),i=77,80)
247			print*,(er(i),i=81,84)
248			print*,(er(i),i=85,88)
249			print*,(er(i),i=89,92)
250			print*,(er(i),i=93,96)
251			print*,(er(i),i=97,100)
252			print*,(er(i),i=101,104)
253			print*,(er(i),i=105,108)
254			print*,(er(i),i=109,112)
255			print*,(er(i),i=113,115)
256			997 continue
257			c yes escape peak:
258			ccc SPH=XTRINTEG(ENATT,ER,EINT,115)
259			SPH=XTRINTEG(ENATT,ER,EINT,75)
260			c if you don't consider the escape-peak, don't comment the next row:
261			C SPH=XTRINTEG(ENATT,EA,EINT,115)
262			C 28/9/2001: FINE TUNING OF TR:
263			c for PS ALFA=0.65 (momentum.lt.40. GeV/c)
264			c per SPS ALFA=0.69 (momentum.ge.40. GeV/c):
265			IF(ALFATR.NE.-9999.) THEN
266			SPH=ALFATR*SPH
267			ELSE
268			TROK=.FALSE.
269			WRITE(CHMAIL,10100) ALFATR
270			CALL GMAIL(1,0)
271			RETURN
272			ENDIF
273			c end 28/9/2001.
274			NPHTR=NPOISS(SPH)
275			c print*,'lay=',lay,'sph,nph=',sph,nph
276			c PRINT*,'Xe-CO2: XTRINTEG,NPOISS:',SPH,NPHTR
277			IF(NPHTR.GT.0) THEN
278			DO I=1,NPHTR
279			ccc 10 E=XTRINTER(RNDM(1)*SPH,EINT,ENATT,115)
280	pamela	3.2	c ml 26/03/04
281			c 10 E=XTRINTER(RNDM(1)*SPH,EINT,ENATT,75)
282			10 CALL GRNDM(GRNDM0,1)
283			E=XTRINTER(GRNDM0(1)*SPH,EINT,ENATT,75)
284			C ml 26/03/04
285	cafagna	3.1	C 28/9/2001: TENTATIVO DI FINE TUNING DELLA TR:
286			******** NEI DATI REALI NON VEDO FOTONI CON ENERGIA MAGGIORE DI 60 keV:
287			c fine modifica 28/9/2001
288			IF(E.GT.45.) THEN
289			PRINT*,'Extracted energy'
290			PRINT*,E
291			GOTO 10
292			ENDIF
293			ENPHTR=ENPHTR+E
294			ENDDO
295			c PRINT*,'Energy (keV) and photons absorbed, for event:'
296			c + ,IEVENT,ENPHTR,NPHTR ,'layer=',lay
297			C NTRHIT=NPHTR
298			C ENEHIT=ENPHTR*1.E-6
299			C* ML: SOTTRAE LA ENERGIA PERSA NEL TRD.
300			GEKINT=GEKIN-ENPHTR*1.E-6
301			GEKIN=GEKINT
302			GETOT=GEKIN +AMASS
303			VECT(7)= SQRT((GETOT+AMASS)*GEKIN)
304			C Routine to find bin number in kinetic energy table stored in ELOW(NEKBIN)
305			CALL GEKBIN
306			C* END ML.
307			ELSE
308			c PRINT*,'no photons converted in the straw'
309			ENDIF
310			IF (LAY.GT.0.AND.LAY.LE.18) THEN
311			ENTRTOT = ENTRTOT + ENPHTR
312			ENLAY(LAY) = ENLAY(LAY) + ENPHTR
313			NPHTOTR = NPHTOTR + NPHTR
314			NPHLAY(LAY)= NPHLAY(LAY) + NPHTR
315			ILI=NUMBV(NVNAME-1)
316			IHI=NUMBV(NVNAME)
317			ENTRSTRAW(ILI,IHI) = ENTRSTRAW(ILI,IHI)+ ENPHTR
318			NTRSTRAW(ILI,IHI) = NTRSTRAW(ILI,IHI)+ NPHTR
319			c PRINT*,'NPHTOTR,LAY,ENPHTR,ENTRTOT',NPHTOTR,LAY,ENPHTR,ENTRTOT
320			C PRINT*,'NTRSTRAW',NTRSTRAW(ILI,IHI),ILI,IHI
321			C PRINT*,'ENTRSTRAW,ENPHTR',ENTRSTRAW(ILI,IHI),ENPHTR
322			ELSE
323			WRITE(CHMAIL,10200)LAY
324			CALL GMAIL(1,0)
325			C PRINT*,' ERROR IN LAYER CALCULATION',LAY
326			ENDIF
327			ENDIF
328			10000 FORMAT('GPXTR error: negative mass =',F10.3)
329			10100 FORMAT('GPXTR error: ALFATR not set, TR process ',
330			+ 'and his tuning will be ignored, ALFATR =',F10.3)
331			10200 FORMAT('GPXTR error in layer calculation =',F10.3)
332			RETURN
333			END