/[PAMELA software]/DarthVader/OrbitalInfo/src/igrf_sub.for
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Annotation of /DarthVader/OrbitalInfo/src/igrf_sub.for

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Revision 1.2 - (hide annotations) (download)
Fri Apr 27 10:35:35 2007 UTC (17 years, 7 months ago) by mocchiut
Branch: MAIN
CVS Tags: v3r04, v3r05, v5r00, v3r03, v4r00, v6r01, v6r00, v3r06
Changes since 1.1: +4 -4 lines
Trying to fix char bug in igrf_sub.for routine

1 mocchiut 1.1 subroutine igrf_sub(xlat,xlong,year,height,
2     & xl,icode,dip,dec)
3     c----------------------------------------------------------------
4     c INPUT:
5     c xlat geodatic latitude in degrees
6     c xlong geodatic longitude in degrees
7     c year decimal year (year+month/12.0-0.5 or year+day-of-year/365
8     c or 366 if leap year)
9     c height height in km
10     c OUTPUT:
11     c xl L value
12     c icode =1 L is correct; =2 L is not correct;
13     c =3 an approximation is used
14     c dip geomagnetic inclination in degrees
15     c dec geomagnetic declination in degress
16     c----------------------------------------------------------------
17    
18     REAL LATI,LONGI
19     COMMON/GENER/ UMR,ERA,AQUAD,BQUAD
20     SAVE /GENER/
21     C
22     CALL INITIZE
23     ibbb=0
24     ALOG2=ALOG(2.)
25     ISTART=1
26     lati=xlat
27     longi=xlong
28     c
29     C----------------CALCULATE PROFILES-----------------------------------
30     c
31     CALL FELDCOF(YEAR,DIMO)
32     CALL FELDG(LATI,LONGI,HEIGHT,BNORTH,BEAST,BDOWN,BABS)
33     CALL SHELLG(LATI,LONGI,HEIGHT,DIMO,XL,ICODE,BAB1)
34     DIP=ASIN(BDOWN/BABS)/UMR
35     DEC=ASIN(BEAST/SQRT(BEAST*BEAST+BNORTH*BNORTH))/UMR
36     RETURN
37     END
38     c
39     c
40     C SHELLIG.FOR, Version 2.0, January 1992
41     C
42     C 11/01/91-DKB- SHELLG: lowest starting point for B0 search is 2
43     C 1/27/92-DKB- Adopted to IGRF-91 coeffcients model
44     C 2/05/92-DKB- Reduce variable-names: INTER(P)SHC,EXTRA(P)SHC,INITI(ALI)ZE
45     C 8/08/95-DKB- Updated to IGRF-45-95; new coeff. DGRF90, IGRF95, IGRF95S
46     C 5/31/00-DKB- Updated to IGRF-45-00; new coeff.: IGRF00, IGRF00s
47     C 3/24/05-DKB- Updated to IGRF-45-10; new coeff.: IGRF05, IGRF05s
48     C 4/25/05-DKB- CALL FELDI and DO 1111 I=1,7 [Alexey Petrov]
49     C
50     C*********************************************************************
51     C SUBROUTINES FINDB0, SHELLG, STOER, FELDG, FELDCOF, GETSHC, *
52     C INTERSHC, EXTRASHC, INITIZE *
53     C*********************************************************************
54     C*********************************************************************
55     C
56     C
57     SUBROUTINE FINDB0(STPS,BDEL,VALUE,BEQU,RR0)
58     C--------------------------------------------------------------------
59     C FINDS SMALLEST MAGNETIC FIELD STRENGTH ON FIELD LINE
60     C
61     C INPUT: STPS STEP SIZE FOR FIELD LINE TRACING
62     C COMMON/FIDB0/
63     C SP DIPOLE ORIENTED COORDINATES FORM SHELLG; P(1,*),
64     C P(2,*), P(3,*) CLOSEST TO MAGNETIC EQUATOR
65     C BDEL REQUIRED ACCURACY = [ B(LAST) - BEQU ] / BEQU
66     C B(LAST) IS FIELD STRENGTH BEFORE BEQU
67     C
68     C OUTPUT: VALUE =.FALSE., IF BEQU IS NOT MINIMAL VALUE ON FIELD LINE
69     C BEQU MAGNETIC FIELD STRENGTH AT MAGNETIC EQUATOR
70     C RR0 EQUATORIAL RADIUS NORMALIZED TO EARTH RADIUS
71     C BDEL FINAL ACHIEVED ACCURACY
72     C--------------------------------------------------------------------
73     DIMENSION P(8,4),SP(3)
74     LOGICAL VALUE
75     COMMON/FIDB0/ SP
76     SAVE /FIDB0/
77     C
78     STEP=STPS
79     IRUN=0
80     7777 IRUN=IRUN+1
81     IF(IRUN.GT.5) THEN
82     VALUE=.FALSE.
83     GOTO 8888
84     ENDIF
85     C*********************FIRST THREE POINTS
86     P(1,2)=SP(1)
87     P(2,2)=SP(2)
88     P(3,2)=SP(3)
89     STEP=-SIGN(STEP,P(3,2))
90     CALL STOER(P(1,2),BQ2,R2)
91     P(1,3)=P(1,2)+0.5*STEP*P(4,2)
92     P(2,3)=P(2,2)+0.5*STEP*P(5,2)
93     P(3,3)=P(3,2)+0.5*STEP
94     CALL STOER(P(1,3),BQ3,R3)
95     P(1,1)=P(1,2)-STEP*(2.*P(4,2)-P(4,3))
96     P(2,1)=P(2,2)-STEP*(2.*P(5,2)-P(5,3))
97     P(3,1)=P(3,2)-STEP
98     CALL STOER(P(1,1),BQ1,R1)
99     P(1,3)=P(1,2)+STEP*(20.*P(4,3)-3.*P(4,2)+P(4,1))/18.
100     P(2,3)=P(2,2)+STEP*(20.*P(5,3)-3.*P(5,2)+P(5,1))/18.
101     P(3,3)=P(3,2)+STEP
102     CALL STOER(P(1,3),BQ3,R3)
103     C******************INVERT SENSE IF REQUIRED
104     IF(BQ3.LE.BQ1) GOTO 2
105     STEP=-STEP
106     R3=R1
107     BQ3=BQ1
108     DO 1 I=1,5
109     ZZ=P(I,1)
110     P(I,1)=P(I,3)
111     1 P(I,3)=ZZ
112     C******************INITIALIZATION
113     2 STEP12=STEP/12.
114     VALUE=.TRUE.
115     BMIN=1.E4
116     BOLD=1.E4
117     C******************CORRECTOR (FIELD LINE TRACING)
118     N=0
119     5555 P(1,3)=P(1,2)+STEP12*(5.*P(4,3)+8.*P(4,2)-P(4,1))
120     N=N+1
121     P(2,3)=P(2,2)+STEP12*(5.*P(5,3)+8.*P(5,2)-P(5,1))
122     C******************PREDICTOR (FIELD LINE TRACING)
123     P(1,4)=P(1,3)+STEP12*(23.*P(4,3)-16.*P(4,2)+5.*P(4,1))
124     P(2,4)=P(2,3)+STEP12*(23.*P(5,3)-16.*P(5,2)+5.*P(5,1))
125     P(3,4)=P(3,3)+STEP
126     CALL STOER(P(1,4),BQ3,R3)
127     DO 1111 J=1,3
128     C DO 1111 I=1,8
129     DO 1111 I=1,7
130     1111 P(I,J)=P(I,J+1)
131     B=SQRT(BQ3)
132     IF(B.LT.BMIN) BMIN=B
133     IF(B.LE.BOLD) THEN
134     BOLD=B
135     ROLD=1./R3
136     SP(1)=P(1,4)
137     SP(2)=P(2,4)
138     SP(3)=P(3,4)
139     GOTO 5555
140     ENDIF
141     IF(BOLD.NE.BMIN) THEN
142     VALUE=.FALSE.
143     ENDIF
144     BDELTA=(B-BOLD)/BOLD
145     IF(BDELTA.GT.BDEL) THEN
146     STEP=STEP/10.
147     GOTO 7777
148     ENDIF
149     8888 RR0=ROLD
150     BEQU=BOLD
151     BDEL=BDELTA
152     RETURN
153     END
154     C
155     C
156     SUBROUTINE SHELLG(GLAT,GLON,ALT,DIMO,FL,ICODE,B0)
157     C--------------------------------------------------------------------
158     C CALCULATES L-VALUE FOR SPECIFIED GEODAETIC COORDINATES, ALTITUDE
159     C AND GEMAGNETIC FIELD MODEL.
160     C REF: G. KLUGE, EUROPEAN SPACE OPERATIONS CENTER, INTERNAL NOTE
161     C NO. 67, 1970.
162     C G. KLUGE, COMPUTER PHYSICS COMMUNICATIONS 3, 31-35, 1972
163     C--------------------------------------------------------------------
164     C CHANGES (D. BILITZA, NOV 87):
165     C - USING CORRECT DIPOL MOMENT I.E.,DIFFERENT COMMON/MODEL/
166     C - USING IGRF EARTH MAGNETIC FIELD MODELS FROM 1945 TO 1990
167     C--------------------------------------------------------------------
168     C INPUT: ENTRY POINT SHELLG
169     C GLAT GEODETIC LATITUDE IN DEGREES (NORTH)
170     C GLON GEODETIC LONGITUDE IN DEGREES (EAST)
171     C ALT ALTITUDE IN KM ABOVE SEA LEVEL
172     C
173     C ENTRY POINT SHELLC
174     C V(3) CARTESIAN COORDINATES IN EARTH RADII (6371.2 KM)
175     C X-AXIS POINTING TO EQUATOR AT 0 LONGITUDE
176     C Y-AXIS POINTING TO EQUATOR AT 90 LONG.
177     C Z-AXIS POINTING TO NORTH POLE
178     C
179     C DIMO DIPOL MOMENT IN GAUSS (NORMALIZED TO EARTH RADIUS)
180     C
181     C COMMON
182     C X(3) NOT USED
183     C H(144) FIELD MODEL COEFFICIENTS ADJUSTED FOR SHELLG
184     C-----------------------------------------------------------------------
185     C OUTPUT: FL L-VALUE
186     C ICODE =1 NORMAL COMPLETION
187     C =2 UNPHYSICAL CONJUGATE POINT (FL MEANINGLESS)
188     C =3 SHELL PARAMETER GREATER THAN LIMIT UP TO
189     C WHICH ACCURATE CALCULATION IS REQUIRED;
190     C APPROXIMATION IS USED.
191     C B0 MAGNETIC FIELD STRENGTH IN GAUSS
192     C-----------------------------------------------------------------------
193     DIMENSION V(3),U(3,3),P(8,100),SP(3)
194     COMMON X(3),H(144)
195     COMMON/FIDB0/ SP
196     SAVE /FIDB0/
197     COMMON/GENER/ UMR,ERA,AQUAD,BQUAD
198     SAVE /GENER/
199     C
200     C-- RMIN, RMAX ARE BOUNDARIES FOR IDENTIFICATION OF ICODE=2 AND 3
201     C-- STEP IS STEP SIZE FOR FIELD LINE TRACING
202     C-- STEQ IS STEP SIZE FOR INTEGRATION
203     C
204     DATA RMIN,RMAX /0.05,1.01/
205     DATA STEP,STEQ /0.20,0.03/
206     BEQU=1.E10
207     C*****ENTRY POINT SHELLG TO BE USED WITH GEODETIC CO-ORDINATES
208     RLAT=GLAT*UMR
209     CT=SIN(RLAT)
210     ST=COS(RLAT)
211     D=SQRT(AQUAD-(AQUAD-BQUAD)*CT*CT)
212     X(1)=(ALT+AQUAD/D)*ST/ERA
213     X(3)=(ALT+BQUAD/D)*CT/ERA
214     RLON=GLON*UMR
215     X(2)=X(1)*SIN(RLON)
216     X(1)=X(1)*COS(RLON)
217     GOTO9
218     ENTRY SHELLC(V,FL,B0)
219     C*****ENTRY POINT SHELLC TO BE USED WITH CARTESIAN CO-ORDINATES
220     X(1)=V(1)
221     X(2)=V(2)
222     X(3)=V(3)
223     C*****CONVERT TO DIPOL-ORIENTED CO-ORDINATES
224     DATA U/ +0.3511737,-0.9148385,-0.1993679,
225     A +0.9335804,+0.3583680,+0.0000000,
226     B +0.0714471,-0.1861260,+0.9799247/
227     9 RQ=1./(X(1)*X(1)+X(2)*X(2)+X(3)*X(3))
228     R3H=SQRT(RQ*SQRT(RQ))
229     P(1,2)=(X(1)*U(1,1)+X(2)*U(2,1)+X(3)*U(3,1))*R3H
230     P(2,2)=(X(1)*U(1,2)+X(2)*U(2,2) )*R3H
231     P(3,2)=(X(1)*U(1,3)+X(2)*U(2,3)+X(3)*U(3,3))*RQ
232     C*****FIRST THREE POINTS OF FIELD LINE
233     STEP=-SIGN(STEP,P(3,2))
234     CALL STOER(P(1,2),BQ2,R2)
235     B0=SQRT(BQ2)
236     P(1,3)=P(1,2)+0.5*STEP*P(4,2)
237     P(2,3)=P(2,2)+0.5*STEP*P(5,2)
238     P(3,3)=P(3,2)+0.5*STEP
239     CALL STOER(P(1,3),BQ3,R3)
240     P(1,1)=P(1,2)-STEP*(2.*P(4,2)-P(4,3))
241     P(2,1)=P(2,2)-STEP*(2.*P(5,2)-P(5,3))
242     P(3,1)=P(3,2)-STEP
243     CALL STOER(P(1,1),BQ1,R1)
244     P(1,3)=P(1,2)+STEP*(20.*P(4,3)-3.*P(4,2)+P(4,1))/18.
245     P(2,3)=P(2,2)+STEP*(20.*P(5,3)-3.*P(5,2)+P(5,1))/18.
246     P(3,3)=P(3,2)+STEP
247     CALL STOER(P(1,3),BQ3,R3)
248     C*****INVERT SENSE IF REQUIRED
249     IF(BQ3.LE.BQ1)GOTO2
250     STEP=-STEP
251     R3=R1
252     BQ3=BQ1
253     DO 1 I=1,7
254     ZZ=P(I,1)
255     P(I,1)=P(I,3)
256     1 P(I,3)=ZZ
257     C*****SEARCH FOR LOWEST MAGNETIC FIELD STRENGTH
258     2 IF(BQ1.LT.BEQU) THEN
259     BEQU=BQ1
260     IEQU=1
261     ENDIF
262     IF(BQ2.LT.BEQU) THEN
263     BEQU=BQ2
264     IEQU=2
265     ENDIF
266     IF(BQ3.LT.BEQU) THEN
267     BEQU=BQ3
268     IEQU=3
269     ENDIF
270     C*****INITIALIZATION OF INTEGRATION LOOPS
271     STEP12=STEP/12.
272     STEP2=STEP+STEP
273     STEQ=SIGN(STEQ,STEP)
274     FI=0.
275     ICODE=1
276     ORADIK=0.
277     OTERM=0.
278     STP=R2*STEQ
279     Z=P(3,2)+STP
280     STP=STP/0.75
281     P(8,1)=STEP2*(P(1,1)*P(4,1)+P(2,1)*P(5,1))
282     P(8,2)=STEP2*(P(1,2)*P(4,2)+P(2,2)*P(5,2))
283     C*****MAIN LOOP (FIELD LINE TRACING)
284     DO 3 N=3,3333
285     C*****CORRECTOR (FIELD LINE TRACING)
286     P(1,N)=P(1,N-1)+STEP12*(5.*P(4,N)+8.*P(4,N-1)-P(4,N-2))
287     P(2,N)=P(2,N-1)+STEP12*(5.*P(5,N)+8.*P(5,N-1)-P(5,N-2))
288     C*****PREPARE EXPANSION COEFFICIENTS FOR INTERPOLATION
289     C*****OF SLOWLY VARYING QUANTITIES
290     P(8,N)=STEP2*(P(1,N)*P(4,N)+P(2,N)*P(5,N))
291     C0=P(1,N-1)**2+P(2,N-1)**2
292     C1=P(8,N-1)
293     C2=(P(8,N)-P(8,N-2))*0.25
294     C3=(P(8,N)+P(8,N-2)-C1-C1)/6.0
295     D0=P(6,N-1)
296     D1=(P(6,N)-P(6,N-2))*0.5
297     D2=(P(6,N)+P(6,N-2)-D0-D0)*0.5
298     E0=P(7,N-1)
299     E1=(P(7,N)-P(7,N-2))*0.5
300     E2=(P(7,N)+P(7,N-2)-E0-E0)*0.5
301     C*****INNER LOOP (FOR QUADRATURE)
302     4 T=(Z-P(3,N-1))/STEP
303     IF(T.GT.1.)GOTO5
304     HLI=0.5*(((C3*T+C2)*T+C1)*T+C0)
305     ZQ=Z*Z
306     R=HLI+SQRT(HLI*HLI+ZQ)
307     IF(R.LE.RMIN)GOTO30
308     RQ=R*R
309     FF=SQRT(1.+3.*ZQ/RQ)
310     RADIK=B0-((D2*T+D1)*T+D0)*R*RQ*FF
311     IF(R-RMAX)44,44,45
312     45 ICODE=2
313     RADIK=RADIK-12.*(R-RMAX)**2
314     44 IF(RADIK+RADIK.LE.ORADIK) GOTO 10
315     TERM=SQRT(RADIK)*FF*((E2*T+E1)*T+E0)/(RQ+ZQ)
316     FI=FI+STP*(OTERM+TERM)
317     ORADIK=RADIK
318     OTERM=TERM
319     STP=R*STEQ
320     Z=Z+STP
321     GOTO4
322     C*****PREDICTOR (FIELD LINE TRACING)
323     5 P(1,N+1)=P(1,N)+STEP12*(23.*P(4,N)-16.*P(4,N-1)+5.*P(4,N-2))
324     P(2,N+1)=P(2,N)+STEP12*(23.*P(5,N)-16.*P(5,N-1)+5.*P(5,N-2))
325     P(3,N+1)=P(3,N)+STEP
326     CALL STOER(P(1,N+1),BQ3,R3)
327     C*****SEARCH FOR LOWEST MAGNETIC FIELD STRENGTH
328     IF(BQ3.LT.BEQU) THEN
329     IEQU=N+1
330     BEQU=BQ3
331     ENDIF
332     3 CONTINUE
333     10 IF(IEQU.lt.2) IEQU=2
334     SP(1)=P(1,IEQU-1)
335     SP(2)=P(2,IEQU-1)
336     SP(3)=P(3,IEQU-1)
337     IF(ORADIK.LT.1E-15)GOTO11
338     FI=FI+STP/0.75*OTERM*ORADIK/(ORADIK-RADIK)
339     C
340     C-- The minimal allowable value of FI was changed from 1E-15 to 1E-12,
341     C-- because 1E-38 is the minimal allowable arg. for ALOG in our envir.
342     C-- D. Bilitza, Nov 87.
343     C
344     11 FI=0.5*ABS(FI)/SQRT(B0)+1E-12
345     C
346     C*****COMPUTE L FROM B AND I. SAME AS CARMEL IN INVAR.
347     C
348     C-- Correct dipole moment is used here. D. Bilitza, Nov 87.
349     C
350     DIMOB0=DIMO/B0
351     arg1=alog(FI)
352     arg2=alog(DIMOB0)
353     c arg = FI*FI*FI/DIMOB0
354     c if(abs(arg).gt.88.0) arg=88.0
355     XX=3*arg1-arg2
356     IF(XX.GT.23.0) GOTO 776
357     IF(XX.GT.11.7) GOTO 775
358     IF(XX.GT.+3.0) GOTO 774
359     IF(XX.GT.-3.0) GOTO 773
360     IF(XX.GT.-22.) GOTO 772
361     771 GG=3.33338E-1*XX+3.0062102E-1
362     GOTO777
363     772 GG=((((((((-8.1537735E-14*XX+8.3232531E-13)*XX+1.0066362E-9)*XX+
364     18.1048663E-8)*XX+3.2916354E-6)*XX+8.2711096E-5)*XX+1.3714667E-3)*
365     2XX+1.5017245E-2)*XX+4.3432642E-1)*XX+6.2337691E-1
366     GOTO777
367     773 GG=((((((((2.6047023E-10*XX+2.3028767E-9)*XX-2.1997983E-8)*XX-
368     15.3977642E-7)*XX-3.3408822E-6)*XX+3.8379917E-5)*XX+1.1784234E-3)*
369     2XX+1.4492441E-2)*XX+4.3352788E-1)*XX+6.228644E-1
370     GOTO777
371     774 GG=((((((((6.3271665E-10*XX-3.958306E-8)*XX+9.9766148E-07)*XX-
372     11.2531932E-5)*XX+7.9451313E-5)*XX-3.2077032E-4)*XX+2.1680398E-3)*
373     2XX+1.2817956E-2)*XX+4.3510529E-1)*XX+6.222355E-1
374     GOTO777
375     775 GG=(((((2.8212095E-8*XX-3.8049276E-6)*XX+2.170224E-4)*XX-6.7310339
376     1E-3)*XX+1.2038224E-1)*XX-1.8461796E-1)*XX+2.0007187E0
377     GOTO777
378     776 GG=XX-3.0460681E0
379     777 FL=EXP(ALOG((1.+EXP(GG))*DIMOB0)/3.0)
380     RETURN
381     C*****APPROXIMATION FOR HIGH VALUES OF L.
382     30 ICODE=3
383     T=-P(3,N-1)/STEP
384     FL=1./(ABS(((C3*T+C2)*T+C1)*T+C0)+1E-15)
385     RETURN
386     END
387     C
388     C
389     SUBROUTINE STOER(P,BQ,R)
390     C*******************************************************************
391     C* SUBROUTINE USED FOR FIELD LINE TRACING IN SHELLG *
392     C* CALLS ENTRY POINT FELDI IN GEOMAGNETIC FIELD SUBROUTINE FELDG *
393     C*******************************************************************
394     DIMENSION P(7),U(3,3)
395     COMMON XI(3),H(144)
396     C*****XM,YM,ZM ARE GEOMAGNETIC CARTESIAN INVERSE CO-ORDINATES
397     ZM=P(3)
398     FLI=P(1)*P(1)+P(2)*P(2)+1E-15
399     R=0.5*(FLI+SQRT(FLI*FLI+(ZM+ZM)**2))
400     RQ=R*R
401     WR=SQRT(R)
402     XM=P(1)*WR
403     YM=P(2)*WR
404     C*****TRANSFORM TO GEOGRAPHIC CO-ORDINATE SYSTEM
405     DATA U/ +0.3511737,-0.9148385,-0.1993679,
406     A +0.9335804,+0.3583680,+0.0000000,
407     B +0.0714471,-0.1861260,+0.9799247/
408     XI(1)=XM*U(1,1)+YM*U(1,2)+ZM*U(1,3)
409     XI(2)=XM*U(2,1)+YM*U(2,2)+ZM*U(2,3)
410     XI(3)=XM*U(3,1) +ZM*U(3,3)
411     C*****COMPUTE DERIVATIVES
412     C CALL FELDI(XI,H)
413     CALL FELDI
414     Q=H(1)/RQ
415     DX=H(3)+H(3)+Q*XI(1)
416     DY=H(4)+H(4)+Q*XI(2)
417     DZ=H(2)+H(2)+Q*XI(3)
418     C*****TRANSFORM BACK TO GEOMAGNETIC CO-ORDINATE SYSTEM
419     DXM=U(1,1)*DX+U(2,1)*DY+U(3,1)*DZ
420     DYM=U(1,2)*DX+U(2,2)*DY
421     DZM=U(1,3)*DX+U(2,3)*DY+U(3,3)*DZ
422     DR=(XM*DXM+YM*DYM+ZM*DZM)/R
423     C*****FORM SLOWLY VARYING EXPRESSIONS
424     P(4)=(WR*DXM-0.5*P(1)*DR)/(R*DZM)
425     P(5)=(WR*DYM-0.5*P(2)*DR)/(R*DZM)
426     DSQ=RQ*(DXM*DXM+DYM*DYM+DZM*DZM)
427     BQ=DSQ*RQ*RQ
428     P(6)=SQRT(DSQ/(RQ+3.*ZM*ZM))
429     P(7)=P(6)*(RQ+ZM*ZM)/(RQ*DZM)
430     RETURN
431     END
432     C
433     C
434     SUBROUTINE FELDG(GLAT,GLON,ALT,BNORTH,BEAST,BDOWN,BABS)
435     C-------------------------------------------------------------------
436     C CALCULATES EARTH MAGNETIC FIELD FROM SPHERICAL HARMONICS MODEL
437     C REF: G. KLUGE, EUROPEAN SPACE OPERATIONS CENTRE, INTERNAL NOTE 61,
438     C 1970.
439     C--------------------------------------------------------------------
440     C CHANGES (D. BILITZA, NOV 87):
441     C - FIELD COEFFICIENTS IN BINARY DATA FILES INSTEAD OF BLOCK DATA
442     C - CALCULATES DIPOL MOMENT
443     C--------------------------------------------------------------------
444     C INPUT: ENTRY POINT FELDG
445     C GLAT GEODETIC LATITUDE IN DEGREES (NORTH)
446     C GLON GEODETIC LONGITUDE IN DEGREES (EAST)
447     C ALT ALTITUDE IN KM ABOVE SEA LEVEL
448     C
449     C ENTRY POINT FELDC
450     C V(3) CARTESIAN COORDINATES IN EARTH RADII (6371.2 KM)
451     C X-AXIS POINTING TO EQUATOR AT 0 LONGITUDE
452     C Y-AXIS POINTING TO EQUATOR AT 90 LONG.
453     C Z-AXIS POINTING TO NORTH POLE
454     C
455     C COMMON BLANK AND ENTRY POINT FELDI ARE NEEDED WHEN USED
456     C IN CONNECTION WITH L-CALCULATION PROGRAM SHELLG.
457     C
458     C COMMON /MODEL/ AND /GENER/
459     C UMR = ATAN(1.0)*4./180. <DEGREE>*UMR=<RADIANT>
460     C ERA EARTH RADIUS FOR NORMALIZATION OF CARTESIAN
461     C COORDINATES (6371.2 KM)
462     C AQUAD, BQUAD SQUARE OF MAJOR AND MINOR HALF AXIS FOR
463     C EARTH ELLIPSOID AS RECOMMENDED BY INTERNATIONAL
464     C ASTRONOMICAL UNION (6378.160, 6356.775 KM).
465     C NMAX MAXIMUM ORDER OF SPHERICAL HARMONICS
466     C TIME YEAR (DECIMAL: 1973.5) FOR WHICH MAGNETIC
467     C FIELD IS TO BE CALCULATED
468     C G(M) NORMALIZED FIELD COEFFICIENTS (SEE FELDCOF)
469     C M=NMAX*(NMAX+2)
470     C------------------------------------------------------------------------
471     C OUTPUT: BABS MAGNETIC FIELD STRENGTH IN GAUSS
472     C BNORTH, BEAST, BDOWN COMPONENTS OF THE FIELD WITH RESPECT
473     C TO THE LOCAL GEODETIC COORDINATE SYSTEM, WITH AXIS
474     C POINTING IN THE TANGENTIAL PLANE TO THE NORTH, EAST
475     C AND DOWNWARD.
476     C-----------------------------------------------------------------------
477     DIMENSION V(3),B(3),G(144)
478     CHARACTER*258 NAME
479     INTEGER NMAX
480     REAL TIME
481     COMMON XI(3),H(144)
482     COMMON/MODEL/ G,NMAX,TIME,NAME
483     SAVE/MODEL/
484     COMMON/GENER/ UMR,ERA,AQUAD,BQUAD
485     SAVE/GENER/
486     C
487     C-- IS RECORDS ENTRY POINT
488     C
489     C*****ENTRY POINT FELDG TO BE USED WITH GEODETIC CO-ORDINATES
490     IS=1
491     RLAT=GLAT*UMR
492     CT=SIN(RLAT)
493     ST=COS(RLAT)
494     D=SQRT(AQUAD-(AQUAD-BQUAD)*CT*CT)
495     RLON=GLON*UMR
496     CP=COS(RLON)
497     SP=SIN(RLON)
498     ZZZ=(ALT+BQUAD/D)*CT/ERA
499     RHO=(ALT+AQUAD/D)*ST/ERA
500     XXX=RHO*CP
501     YYY=RHO*SP
502     GOTO10
503     ENTRY FELDC(V,B)
504     C*****ENTRY POINT FELDC TO BE USED WITH CARTESIAN CO-ORDINATES
505     IS=2
506     XXX=V(1)
507     YYY=V(2)
508     ZZZ=V(3)
509     10 RQ=1./(XXX*XXX+YYY*YYY+ZZZ*ZZZ)
510     XI(1)=XXX*RQ
511     XI(2)=YYY*RQ
512     XI(3)=ZZZ*RQ
513     GOTO20
514     ENTRY FELDI
515     C*****ENTRY POINT FELDI USED FOR L COMPUTATION
516     IS=3
517     20 IHMAX=NMAX*NMAX+1
518     LAST=IHMAX+NMAX+NMAX
519     IMAX=NMAX+NMAX-1
520     DO 8 I=IHMAX,LAST
521     8 H(I)=G(I)
522     DO 6 K=1,3,2
523     I=IMAX
524     IH=IHMAX
525     1 IL=IH-I
526     F=2./FLOAT(I-K+2)
527     X=XI(1)*F
528     Y=XI(2)*F
529     Z=XI(3)*(F+F)
530     I=I-2
531     IF(I-1)5,4,2
532     2 DO 3 M=3,I,2
533     H(IL+M+1)=G(IL+M+1)+Z*H(IH+M+1)+X*(H(IH+M+3)-H(IH+M-1))
534     A -Y*(H(IH+M+2)+H(IH+M-2))
535     3 H(IL+M)=G(IL+M)+Z*H(IH+M)+X*(H(IH+M+2)-H(IH+M-2))
536     A +Y*(H(IH+M+3)+H(IH+M-1))
537     4 H(IL+2)=G(IL+2)+Z*H(IH+2)+X*H(IH+4)-Y*(H(IH+3)+H(IH))
538     H(IL+1)=G(IL+1)+Z*H(IH+1)+Y*H(IH+4)+X*(H(IH+3)-H(IH))
539     5 H(IL)=G(IL)+Z*H(IH)+2.*(X*H(IH+1)+Y*H(IH+2))
540     IH=IL
541     IF(I.GE.K)GOTO1
542     6 CONTINUE
543     IF(IS.EQ.3)RETURN
544     S=.5*H(1)+2.*(H(2)*XI(3)+H(3)*XI(1)+H(4)*XI(2))
545     T=(RQ+RQ)*SQRT(RQ)
546     BXXX=T*(H(3)-S*XXX)
547     BYYY=T*(H(4)-S*YYY)
548     BZZZ=T*(H(2)-S*ZZZ)
549     IF(IS.EQ.2)GOTO7
550     BABS=SQRT(BXXX*BXXX+BYYY*BYYY+BZZZ*BZZZ)
551     BEAST=BYYY*CP-BXXX*SP
552     BRHO=BYYY*SP+BXXX*CP
553     BNORTH=BZZZ*ST-BRHO*CT
554     BDOWN=-BZZZ*CT-BRHO*ST
555     RETURN
556     7 B(1)=BXXX
557     B(2)=BYYY
558     B(3)=BZZZ
559     RETURN
560     END
561     C
562     C
563     SUBROUTINE FELDCOF(YEAR,DIMO)
564     C------------------------------------------------------------------------
565     C DETERMINES COEFFICIENTS AND DIPOL MOMENT FROM IGRF MODELS
566     C
567     C INPUT: YEAR DECIMAL YEAR FOR WHICH GEOMAGNETIC FIELD IS TO
568     C BE CALCULATED
569     C OUTPUT: DIMO GEOMAGNETIC DIPOL MOMENT IN GAUSS (NORMALIZED
570     C TO EARTH'S RADIUS) AT THE TIME (YEAR)
571     C D. BILITZA, NSSDC, GSFC, CODE 633, GREENBELT, MD 20771,
572     C (301)286-9536 NOV 1987.
573     C ### updated to IGRF-2000 version -dkb- 5/31/2000
574     C ### updated to IGRF-2005 version -dkb- 3/24/2000
575     C-----------------------------------------------------------------------
576     CHARACTER*258 FIL1, FIL2
577     CHARACTER*258 FILMOD
578     C ### FILMOD, DTEMOD arrays +1
579     c DIMENSION GH1(144),GH2(120),GHA(144),FILMOD(14),DTEMOD(14)
580     DIMENSION GH1(144),GH2(120),GHA(144),FILMOD(3),DTEMOD(3)
581     DOUBLE PRECISION X,F0,F
582     INTEGER L1,L2,L3
583     INTEGER NMAX
584     REAL TIME
585     CHARACTER *258 P1,P2,P3
586     COMMON/PPATH/ L1,L2,L3,P1, P2, P3
587     SAVE/PPATH/
588     COMMON/MODEL/ GH1,NMAX,TIME,FIL1
589     SAVE/MODEL/
590     COMMON/GENER/ UMR,ERAD,AQUAD,BQUAD
591     SAVE/GENER/
592     C ### updated to 2005
593     C CHARACTER COEFPATH*80, COEF1*80, COEF2*80, COEF3*80
594    
595     c COEFPATH = 'OrbitalInfo/src/'
596     c COEF1 = 'dgrf00.dat'
597     c COEF2 = 'igrf05.dat'
598     c COEF3 = 'igrf05s.dat'
599     c COEF1 = COEFPATH(1:16)//COEF1
600     c COEF2 = COEFPATH(1:16)//COEF2
601     c COEF3 = COEFPATH(1:16)//COEF3
602     c FILMOD(1) = COEF1
603     c FILMOD(2) = COEF2
604     c FILMOD(3) = COEF3
605     FILMOD(1) = P1(1:L1)
606     FILMOD(2) = P2(1:L2)
607     FILMOD(3) = P3(1:L3)
608     c FILMOD(1) = 'OrbitalInfo/src/dgrf00.dat'
609     c FILMOD(2) = 'OrbitalInfo/src/igrf05.dat'
610     c FILMOD(3) = 'OrbitalInfo/src/igrf05s.dat'
611     c WRITE(*,*) FILMOD(1)
612     c WRITE(*,*) FILMOD(2)
613     c WRITE(*,*) FILMOD(3)
614     c DATA FILMOD / 'dgrf00.dat', 'igrf05.dat', 'igrf05s.dat'/
615     DATA DTEMOD / 2000., 2005., 2010./
616     c
617     c DATA FILMOD /'dgrf45.dat', 'dgrf50.dat',
618     c 1 'dgrf55.dat', 'dgrf60.dat', 'dgrf65.dat',
619     c 2 'dgrf70.dat', 'dgrf75.dat', 'dgrf80.dat',
620     c 3 'dgrf85.dat', 'dgrf90.dat', 'dgrf95.dat',
621     c 4 'dgrf00.dat','igrf05.dat','igrf05s.dat'/
622     c DATA DTEMOD / 1945., 1950., 1955., 1960., 1965., 1970.,
623     c 1 1975., 1980., 1985., 1990., 1995., 2000.,2005.,2010./
624     C
625     C ### numye = numye + 1 ; is number of years represented by IGRF
626     C
627     c NUMYE=13
628     NUMYE=2
629    
630     C
631     C IS=0 FOR SCHMIDT NORMALIZATION IS=1 GAUSS NORMALIZATION
632     C IU IS INPUT UNIT NUMBER FOR IGRF COEFFICIENT SETS
633     C
634     IU = 10
635     IS = 0
636     C-- DETERMINE IGRF-YEARS FOR INPUT-YEAR
637     TIME = YEAR
638     IYEA = INT(YEAR/5.)*5
639     c L = (IYEA - 1945)/5 + 1
640     L = (IYEA - 2000)/5 + 1
641     IF(L.LT.1) L=1
642     IF(L.GT.NUMYE) L=NUMYE
643     DTE1 = DTEMOD(L)
644     FIL1 = FILMOD(L)
645     DTE2 = DTEMOD(L+1)
646     FIL2 = FILMOD(L+1)
647     C-- GET IGRF COEFFICIENTS FOR THE BOUNDARY YEARS
648     CALL GETSHC (IU, FIL1, NMAX1, ERAD, GH1, IER)
649     IF (IER .NE. 0) STOP
650     CALL GETSHC (IU, FIL2, NMAX2, ERAD, GH2, IER)
651     IF (IER .NE. 0) STOP
652     C-- DETERMINE IGRF COEFFICIENTS FOR YEAR
653     IF (L .LE. NUMYE-1) THEN
654     CALL INTERSHC (YEAR, DTE1, NMAX1, GH1, DTE2,
655     1 NMAX2, GH2, NMAX, GHA)
656     ELSE
657     CALL EXTRASHC (YEAR, DTE1, NMAX1, GH1, NMAX2,
658     1 GH2, NMAX, GHA)
659     ENDIF
660     C-- DETERMINE MAGNETIC DIPOL MOMENT AND COEFFIECIENTS G
661     F0=0.D0
662     DO 1234 J=1,3
663     F = GHA(J) * 1.D-5
664     F0 = F0 + F * F
665     1234 CONTINUE
666     DIMO = DSQRT(F0)
667    
668     GH1(1) = 0.0
669     I=2
670     F0=1.D-5
671     IF(IS.EQ.0) F0=-F0
672     SQRT2=SQRT(2.)
673    
674     DO 9 N=1,NMAX
675     X = N
676     F0 = F0 * X * X / (4.D0 * X - 2.D0)
677     IF(IS.EQ.0) F0 = F0 * (2.D0 * X - 1.D0) / X
678     F = F0 * 0.5D0
679     IF(IS.EQ.0) F = F * SQRT2
680     GH1(I) = GHA(I-1) * F0
681     I = I+1
682     DO 9 M=1,N
683     F = F * (X + M) / (X - M + 1.D0)
684     IF(IS.EQ.0) F = F * DSQRT((X - M + 1.D0) / (X + M))
685     GH1(I) = GHA(I-1) * F
686     GH1(I+1) = GHA(I) * F
687     I=I+2
688     9 CONTINUE
689     RETURN
690     END
691     C
692     C
693     SUBROUTINE GETSHC (IU, FSPEC, NMAX, ERAD, GH, IER)
694    
695     C ===============================================================
696     C
697     C Version 1.01
698     C
699     C Reads spherical harmonic coefficients from the specified
700     C file into an array.
701     C
702     C Input:
703     C IU - Logical unit number
704     C FSPEC - File specification
705     C
706     C Output:
707     C NMAX - Maximum degree and order of model
708     C ERAD - Earth's radius associated with the spherical
709     C harmonic coefficients, in the same units as
710     C elevation
711     C GH - Schmidt quasi-normal internal spherical
712     C harmonic coefficients
713     C IER - Error number: = 0, no error
714     C = -2, records out of order
715     C = FORTRAN run-time error number
716     C
717     C A. Zunde
718     C USGS, MS 964, Box 25046 Federal Center, Denver, CO 80225
719     C
720     C ===============================================================
721    
722     CHARACTER FSPEC*(*), FOUT*258
723     DIMENSION GH(*)
724     C ---------------------------------------------------------------
725     C Open coefficient file. Read past first header record.
726     C Read degree and order of model and Earth's radius.
727     C ---------------------------------------------------------------
728     WRITE(FOUT,667) FSPEC
729     c 667 FORMAT('/usr/local/etc/httpd/cgi-bin/natasha/IRI/',A12)
730     667 FORMAT(A258)
731     OPEN (IU, FILE=FOUT, STATUS='OLD', IOSTAT=IER, ERR=999)
732     READ (IU, *, IOSTAT=IER, ERR=999)
733     READ (IU, *, IOSTAT=IER, ERR=999) NMAX, ERAD
734     C ---------------------------------------------------------------
735     C Read the coefficient file, arranged as follows:
736     C
737     C N M G H
738     C ----------------------
739     C / 1 0 GH(1) -
740     C / 1 1 GH(2) GH(3)
741     C / 2 0 GH(4) -
742     C / 2 1 GH(5) GH(6)
743     C NMAX*(NMAX+3)/2 / 2 2 GH(7) GH(8)
744     C records \ 3 0 GH(9) -
745     C \ . . . .
746     C \ . . . .
747     C NMAX*(NMAX+2) \ . . . .
748     C elements in GH \ NMAX NMAX . .
749     C
750     C N and M are, respectively, the degree and order of the
751     C coefficient.
752     C ---------------------------------------------------------------
753    
754     I = 0
755     DO 2211 NN = 1, NMAX
756     DO 2233 MM = 0, NN
757     READ (IU, *, IOSTAT=IER, ERR=999) N, M, G, H
758     IF (NN .NE. N .OR. MM .NE. M) THEN
759     IER = -2
760     GOTO 999
761     ENDIF
762     I = I + 1
763     GH(I) = G
764     IF (M .NE. 0) THEN
765     I = I + 1
766     GH(I) = H
767     ENDIF
768     2233 CONTINUE
769     2211 CONTINUE
770    
771     999 CLOSE (IU)
772    
773    
774     RETURN
775     END
776     C
777     C
778     SUBROUTINE INTERSHC (DATE, DTE1, NMAX1, GH1, DTE2,
779     1 NMAX2, GH2, NMAX, GH)
780    
781     C ===============================================================
782     C
783     C Version 1.01
784     C
785     C Interpolates linearly, in time, between two spherical
786     C harmonic models.
787     C
788     C Input:
789     C DATE - Date of resulting model (in decimal year)
790     C DTE1 - Date of earlier model
791     C NMAX1 - Maximum degree and order of earlier model
792     C GH1 - Schmidt quasi-normal internal spherical
793     C harmonic coefficients of earlier model
794     C DTE2 - Date of later model
795     C NMAX2 - Maximum degree and order of later model
796     C GH2 - Schmidt quasi-normal internal spherical
797     C harmonic coefficients of later model
798     C
799     C Output:
800     C GH - Coefficients of resulting model
801     C NMAX - Maximum degree and order of resulting model
802     C
803     C A. Zunde
804     C USGS, MS 964, Box 25046 Federal Center, Denver, CO 80225
805     C
806     C ===============================================================
807    
808     DIMENSION GH1(*), GH2(*), GH(*)
809    
810     C ---------------------------------------------------------------
811     C The coefficients (GH) of the resulting model, at date
812     C DATE, are computed by linearly interpolating between the
813     C coefficients of the earlier model (GH1), at date DTE1,
814     C and those of the later model (GH2), at date DTE2. If one
815     C model is smaller than the other, the interpolation is
816     C performed with the missing coefficients assumed to be 0.
817     C ---------------------------------------------------------------
818    
819     FACTOR = (DATE - DTE1) / (DTE2 - DTE1)
820    
821     IF (NMAX1 .EQ. NMAX2) THEN
822     K = NMAX1 * (NMAX1 + 2)
823     NMAX = NMAX1
824     ELSE IF (NMAX1 .GT. NMAX2) THEN
825     K = NMAX2 * (NMAX2 + 2)
826     L = NMAX1 * (NMAX1 + 2)
827     DO 1122 I = K + 1, L
828     1122 GH(I) = GH1(I) + FACTOR * (-GH1(I))
829     NMAX = NMAX1
830     ELSE
831     K = NMAX1 * (NMAX1 + 2)
832     L = NMAX2 * (NMAX2 + 2)
833     DO 1133 I = K + 1, L
834     1133 GH(I) = FACTOR * GH2(I)
835     NMAX = NMAX2
836     ENDIF
837    
838     DO 1144 I = 1, K
839     1144 GH(I) = GH1(I) + FACTOR * (GH2(I) - GH1(I))
840    
841     RETURN
842     END
843     C
844     C
845     SUBROUTINE EXTRASHC (DATE, DTE1, NMAX1, GH1, NMAX2,
846     1 GH2, NMAX, GH)
847    
848     C ===============================================================
849     C
850     C Version 1.01
851     C
852     C Extrapolates linearly a spherical harmonic model with a
853     C rate-of-change model.
854     C
855     C Input:
856     C DATE - Date of resulting model (in decimal year)
857     C DTE1 - Date of base model
858     C NMAX1 - Maximum degree and order of base model
859     C GH1 - Schmidt quasi-normal internal spherical
860     C harmonic coefficients of base model
861     C NMAX2 - Maximum degree and order of rate-of-change
862     C model
863     C GH2 - Schmidt quasi-normal internal spherical
864     C harmonic coefficients of rate-of-change model
865     C
866     C Output:
867     C GH - Coefficients of resulting model
868     C NMAX - Maximum degree and order of resulting model
869     C
870     C A. Zunde
871     C USGS, MS 964, Box 25046 Federal Center, Denver, CO 80225
872     C
873     C ===============================================================
874    
875     DIMENSION GH1(*), GH2(*), GH(*)
876    
877     C ---------------------------------------------------------------
878     C The coefficients (GH) of the resulting model, at date
879     C DATE, are computed by linearly extrapolating the coef-
880     C ficients of the base model (GH1), at date DTE1, using
881     C those of the rate-of-change model (GH2), at date DTE2. If
882     C one model is smaller than the other, the extrapolation is
883     C performed with the missing coefficients assumed to be 0.
884     C ---------------------------------------------------------------
885    
886     FACTOR = (DATE - DTE1)
887    
888     IF (NMAX1 .EQ. NMAX2) THEN
889     K = NMAX1 * (NMAX1 + 2)
890     NMAX = NMAX1
891     ELSE IF (NMAX1 .GT. NMAX2) THEN
892     K = NMAX2 * (NMAX2 + 2)
893     L = NMAX1 * (NMAX1 + 2)
894     DO 1155 I = K + 1, L
895     1155 GH(I) = GH1(I)
896     NMAX = NMAX1
897     ELSE
898     K = NMAX1 * (NMAX1 + 2)
899     L = NMAX2 * (NMAX2 + 2)
900     DO 1166 I = K + 1, L
901     1166 GH(I) = FACTOR * GH2(I)
902     NMAX = NMAX2
903     ENDIF
904    
905     DO 1177 I = 1, K
906     1177 GH(I) = GH1(I) + FACTOR * GH2(I)
907    
908     RETURN
909     END
910     C
911     C
912     SUBROUTINE INITIZE(TP1,TL1,TP2,TL2,TP3,TL3)
913     C----------------------------------------------------------------
914     C Initializes the parameters in COMMON/GENER/
915     C
916     C UMR = ATAN(1.0)*4./180. <DEGREE>*UMR=<RADIANT>
917     C ERA EARTH RADIUS FOR NORMALIZATION OF CARTESIAN
918     C COORDINATES (6371.2 KM)
919     C EREQU MAJOR HALF AXIS FOR EARTH ELLIPSOID (6378.160 KM)
920     C ERPOL MINOR HALF AXIS FOR EARTH ELLIPSOID (6356.775 KM)
921     C AQUAD SQUARE OF MAJOR HALF AXIS FOR EARTH ELLIPSOID
922     C BQUAD SQUARE OF MINOR HALF AXIS FOR EARTH ELLIPSOID
923     C
924     C ERA, EREQU and ERPOL as recommended by the INTERNATIONAL
925     C ASTRONOMICAL UNION .
926     C-----------------------------------------------------------------
927     INTEGER TL1,TL2,TL3
928     CHARACTER *258 TP1,TP2,TP3
929     INTEGER L1,L2,L3
930     CHARACTER *258 P1,P2,P3
931     COMMON/PPATH/ L1,L2,L3,P1, P2, P3
932     SAVE/PPATH/
933    
934 mocchiut 1.2 COMMON/GENER/UMR,ERA,AQUAD,BQUAD
935 mocchiut 1.1 SAVE/GENER/
936    
937     L1 = TL1
938     L2 = TL2
939     L3 = TL3
940 mocchiut 1.2 P1 = TP1(1:L1)
941     P2 = TP2(1:L2)
942     P3 = TP3(1:L3)
943 mocchiut 1.1
944     ERA=6371.2
945     EREQU=6378.16
946     ERPOL=6356.775
947     AQUAD=EREQU*EREQU
948     BQUAD=ERPOL*ERPOL
949     UMR=ATAN(1.0)*4./180.
950     RETURN
951     END

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