gpamela/gpfield/gufld.F

*
* $Id: gufld.F,v 3.1.1.1 2002/07/11 16:02:01 cafagna Exp $
*
* $Log: gufld.F,v $
* Revision 3.1.1.1  2002/07/11 16:02:01  cafagna
* First GPAMELA release on CVS
*
*
*CMZ :  2.01/00 06/03/2000  13.07.03  by  Francesco Cafagna
*CMZ :  2.00/00 03/03/2000  15.39.05  by  Francesco Cafagna
*CMZU:  1.01/00 26/04/96  15.12.30  by  Paolo (The Magic) Papini
*-- Author :
      SUBROUTINE GUFLD(V,F)
************************************************************************
*                                                                      *
* To map Pamela magnetic field                                         *
* A bit of housekeeping: delete print statement etc. etc., by F. Caf.  *
*                                                                      *
* Variables definition:                                                *
* IN:                                                                  *
*  V , vector with coordinates in MARS                                 *
* OUT:                                                                 *
*  F , Magnetic field components along X, Y and Z                      *
*                                                                      *
* Called by: GHELIX, GRKUTA                                            *
* Author: Paolo Papini   16/02/96                                      *
*                                                                      *
************************************************************************
#include "gpfield.inc"
      REAL*8 VVINT(3),FFINT(3)
      REAL V(3),F(3)
      REAL*8 CM_TO_M , TESLA_TO_KGAUSS
      PARAMETER(CM_TO_M=1.D-2 , TESLA_TO_KGAUSS = 1.D1)
    

C*
C      INTEGER II,III
C      REAL DISM,F0X,F0Y,F0Z,F1X,F1Y,F1Z,F2X,F2Y,F2Z,
C     +     F3X,F3Y,F3Z
C      REAL V(3),F(3),AV(3)
C*
C* Transform coordinates to Spectrometer frame
C*
C      CALL GPMASPE(V)
C*
C* Take just the absolute value for the coordinates
C*
C      DO I=1,3
C         AV(I) = ABS( V(I) )
C      ENDDO
C      F(1)=0.
C      F(2)=0.
C      F(3)=0.
C*
C* Check if we are outside the map
C*
C      IF( (AV(1).GE.20).OR.(AV(2).GE.20).OR.(AV(3).GE.60.) )
C     +    GOTO 10
C      IV(1)=INT(AV(1)*2.)+1
C      IV(2)=INT(AV(2)*2.)+1
C      IV(3)=INT(AV(3)/2.)+1
C      DO I1=0,1
C         DO I2=0,1
C            DO I3=0,1
C               II=I1*4+I2*2+I3+1
C               VV(II,1)=FLOAT(IV(1)+I1-1)*0.5
C               VV(II,2)=FLOAT(IV(2)+I2-1)*0.5
C               VV(II,3)=FLOAT(IV(3)+I3-1)*2.
C               IVV(II,1)=IV(1)+I1
C               IVV(II,2)=IV(2)+I2
C               IVV(II,3)=IV(3)+I3
C               DD(II)=(VV(II,1)-AV(1))**2 + (VV(II,2)-AV(2))**2 +
C     +         (VV(II,3)-AV(3))**2
C            ENDDO
C         ENDDO
C      ENDDO
C* --- v0
C      DISM=1.E9
C      II=0
C      DO I=1,8
C         IF(DD(I).LT.DISM) THEN
C            DISM=DD(I)
C            II=I
C         END IF
C      END DO
C      DO I=1,3
C         V0(I)=VV(II,I)
C      END DO
C      F0X=FX(IVV(II,1),IVV(II,2),IVV(II,3))
C      F0Y=FY(IVV(II,1),IVV(II,2),IVV(II,3))
C      F0Z=FZ(IVV(II,1),IVV(II,2),IVV(II,3))
C* --- v1
C      V1(2)=V0(2)
C      V1(3)=V0(3)
C      IF(AV(1).GE.V0(1)) THEN
C         III=IVV(II,1)+1
C         V1(1)=V0(1)+0.5
C      ELSE
C         III=IVV(II,1)-1
C         V1(1)=V0(1)-0.5
C      END IF
C      F1X=FX(III,IVV(II,2),IVV(II,3))
C      F1Y=FY(III,IVV(II,2),IVV(II,3))
C      F1Z=FZ(III,IVV(II,2),IVV(II,3))
C* --- v2
C      V2(1)=V0(1)
C      V2(3)=V0(3)
C      IF(AV(2).GE.V0(2)) THEN
C         III=IVV(II,2)+1
C         V2(2)=V0(2)+0.5
C      ELSE
C         III=IVV(II,2)-1
C         V2(2)=V0(2)-0.5
C      END IF
C      F2X=FX(IVV(II,1),III,IVV(II,3))
C      F2Y=FY(IVV(II,1),III,IVV(II,3))
C      F2Z=FZ(IVV(II,1),III,IVV(II,3))
C* --- v3
C      V3(1)=V0(1)
C      V3(2)=V0(2)
C      IF(AV(3).GE.V0(3)) THEN
C         III=IVV(II,3)+1
C         V3(3)=V0(3)+2.
C      ELSE
C         III=IVV(II,3)-1
C         V3(3)=V0(3)-2.
C      END IF
C      F3X=FX(IVV(II,1),IVV(II,2),III)
C      F3Y=FY(IVV(II,1),IVV(II,2),III)
C      F3Z=FZ(IVV(II,1),IVV(II,2),III)
C* --- linear interpolation, magnetic field calculation
C      CALL FLIN3(V0,V1,V2,V3,F0X,F1X,F2X,F3X,AV,F(1))
C      CALL FLIN3(V0,V1,V2,V3,F0Y,F1Y,F2Y,F3Y,AV,F(2))
C      CALL FLIN3(V0,V1,V2,V3,F0Z,F1Z,F2Z,F3Z,AV,F(3))
C* --- mirroing
C      IF(V(2).LT.0.) THEN
C         F(1)=-1.*F(1)
C         F(3)=-1.*F(3)
C      END IF
C      IF(V(1).LT.0.) F(1)=-1.*F(1)
C      IF(V(3).LT.0.) F(3)=-1.*F(3)
C*
C* Transform coordinates back to MARS
C*
C   10 CALL GPSPEMA(V)
C      RETURN
C      END

*

   
*
* Transform coordinates to Spectrometer frame
*
      CALL GPMASPE(V)
*
* INTERFACE TO TRACKER FIELD ROUTINES
*      
      DO I=1,3
         VVINT(I) = DBLE(V(I)) * CM_TO_M
      ENDDO
      
      CALL inter_B(VVINT(1),VVINT(2),VVINT(3),FFINT) !coordinates in m, Field in Tesla

      DO I=1,3
         F(I) = REAL( FFINT(I) * TESLA_TO_KGAUSS )
      ENDDO
      
*
* Transform coordinates back to MARS
*
   10 CALL GPSPEMA(V)
      RETURN
      END
1	cafagna	3.1	*
2	pam-ba	3.2	* $Id: gufld.F,v 3.1.1.1 2002/07/11 16:02:01 cafagna Exp $
3			*
4			* $Log: gufld.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 : 2.01/00 06/03/2000 13.07.03 by Francesco Cafagna
10			*CMZ : 2.00/00 03/03/2000 15.39.05 by Francesco Cafagna
11			*CMZU: 1.01/00 26/04/96 15.12.30 by Paolo (The Magic) Papini
12			*-- Author :
13			SUBROUTINE GUFLD(V,F)
14			************************************************************************
15			* *
16			* To map Pamela magnetic field *
17			* A bit of housekeeping: delete print statement etc. etc., by F. Caf. *
18			* *
19			* Variables definition: *
20			* IN: *
21			* V , vector with coordinates in MARS *
22			* OUT: *
23			* F , Magnetic field components along X, Y and Z *
24			* *
25			* Called by: GHELIX, GRKUTA *
26			* Author: Paolo Papini 16/02/96 *
27			* *
28			************************************************************************
29			#include "gpfield.inc"
30	pam-ba	3.2	REAL*8 VVINT(3),FFINT(3)
31			REAL V(3),F(3)
32			REAL*8 CM_TO_M , TESLA_TO_KGAUSS
33			PARAMETER(CM_TO_M=1.D-2 , TESLA_TO_KGAUSS = 1.D1)
34
35
36			C*
37			C INTEGER II,III
38			C REAL DISM,F0X,F0Y,F0Z,F1X,F1Y,F1Z,F2X,F2Y,F2Z,
39			C + F3X,F3Y,F3Z
40			C REAL V(3),F(3),AV(3)
41			C*
42			C* Transform coordinates to Spectrometer frame
43			C*
44			C CALL GPMASPE(V)
45			C*
46			C* Take just the absolute value for the coordinates
47			C*
48			C DO I=1,3
49			C AV(I) = ABS( V(I) )
50			C ENDDO
51			C F(1)=0.
52			C F(2)=0.
53			C F(3)=0.
54			C*
55			C* Check if we are outside the map
56			C*
57			C IF( (AV(1).GE.20).OR.(AV(2).GE.20).OR.(AV(3).GE.60.) )
58			C + GOTO 10
59			C IV(1)=INT(AV(1)*2.)+1
60			C IV(2)=INT(AV(2)*2.)+1
61			C IV(3)=INT(AV(3)/2.)+1
62			C DO I1=0,1
63			C DO I2=0,1
64			C DO I3=0,1
65			C II=I14+I22+I3+1
66			C VV(II,1)=FLOAT(IV(1)+I1-1)*0.5
67			C VV(II,2)=FLOAT(IV(2)+I2-1)*0.5
68			C VV(II,3)=FLOAT(IV(3)+I3-1)*2.
69			C IVV(II,1)=IV(1)+I1
70			C IVV(II,2)=IV(2)+I2
71			C IVV(II,3)=IV(3)+I3
72			C DD(II)=(VV(II,1)-AV(1))2 + (VV(II,2)-AV(2))2 +
73			C + (VV(II,3)-AV(3))**2
74			C ENDDO
75			C ENDDO
76			C ENDDO
77			C* --- v0
78			C DISM=1.E9
79			C II=0
80			C DO I=1,8
81			C IF(DD(I).LT.DISM) THEN
82			C DISM=DD(I)
83			C II=I
84			C END IF
85			C END DO
86			C DO I=1,3
87			C V0(I)=VV(II,I)
88			C END DO
89			C F0X=FX(IVV(II,1),IVV(II,2),IVV(II,3))
90			C F0Y=FY(IVV(II,1),IVV(II,2),IVV(II,3))
91			C F0Z=FZ(IVV(II,1),IVV(II,2),IVV(II,3))
92			C* --- v1
93			C V1(2)=V0(2)
94			C V1(3)=V0(3)
95			C IF(AV(1).GE.V0(1)) THEN
96			C III=IVV(II,1)+1
97			C V1(1)=V0(1)+0.5
98			C ELSE
99			C III=IVV(II,1)-1
100			C V1(1)=V0(1)-0.5
101			C END IF
102			C F1X=FX(III,IVV(II,2),IVV(II,3))
103			C F1Y=FY(III,IVV(II,2),IVV(II,3))
104			C F1Z=FZ(III,IVV(II,2),IVV(II,3))
105			C* --- v2
106			C V2(1)=V0(1)
107			C V2(3)=V0(3)
108			C IF(AV(2).GE.V0(2)) THEN
109			C III=IVV(II,2)+1
110			C V2(2)=V0(2)+0.5
111			C ELSE
112			C III=IVV(II,2)-1
113			C V2(2)=V0(2)-0.5
114			C END IF
115			C F2X=FX(IVV(II,1),III,IVV(II,3))
116			C F2Y=FY(IVV(II,1),III,IVV(II,3))
117			C F2Z=FZ(IVV(II,1),III,IVV(II,3))
118			C* --- v3
119			C V3(1)=V0(1)
120			C V3(2)=V0(2)
121			C IF(AV(3).GE.V0(3)) THEN
122			C III=IVV(II,3)+1
123			C V3(3)=V0(3)+2.
124			C ELSE
125			C III=IVV(II,3)-1
126			C V3(3)=V0(3)-2.
127			C END IF
128			C F3X=FX(IVV(II,1),IVV(II,2),III)
129			C F3Y=FY(IVV(II,1),IVV(II,2),III)
130			C F3Z=FZ(IVV(II,1),IVV(II,2),III)
131			C* --- linear interpolation, magnetic field calculation
132			C CALL FLIN3(V0,V1,V2,V3,F0X,F1X,F2X,F3X,AV,F(1))
133			C CALL FLIN3(V0,V1,V2,V3,F0Y,F1Y,F2Y,F3Y,AV,F(2))
134			C CALL FLIN3(V0,V1,V2,V3,F0Z,F1Z,F2Z,F3Z,AV,F(3))
135			C* --- mirroing
136			C IF(V(2).LT.0.) THEN
137			C F(1)=-1.*F(1)
138			C F(3)=-1.*F(3)
139			C END IF
140			C IF(V(1).LT.0.) F(1)=-1.*F(1)
141			C IF(V(3).LT.0.) F(3)=-1.*F(3)
142			C*
143			C* Transform coordinates back to MARS
144			C*
145			C 10 CALL GPSPEMA(V)
146			C RETURN
147			C END
148
149	cafagna	3.1	*
150	pam-ba	3.2
151
152	cafagna	3.1	*
153			* Transform coordinates to Spectrometer frame
154			*
155			CALL GPMASPE(V)
156			*
157	pam-ba	3.2	* INTERFACE TO TRACKER FIELD ROUTINES
158			*
159	cafagna	3.1	DO I=1,3
160	pam-ba	3.2	VVINT(I) = DBLE(V(I)) * CM_TO_M
161	cafagna	3.1	ENDDO
162	pam-ba	3.2
163			CALL inter_B(VVINT(1),VVINT(2),VVINT(3),FFINT) !coordinates in m, Field in Tesla
164
165			DO I=1,3
166			F(I) = REAL( FFINT(I) * TESLA_TO_KGAUSS )
167	cafagna	3.1	ENDDO
168	pam-ba	3.2
169	cafagna	3.1	*
170			* Transform coordinates back to MARS
171			*
172			10 CALL GPSPEMA(V)
173			RETURN
174			END