WSJT-X/libm65/moon2.f90
Joe Taylor e5c1c14543 More conversions of .f to .f90.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/map65@7474 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
2017-01-10 16:20:25 +00:00

164 lines
6.3 KiB
Fortran

subroutine moon2(y,m,Day,UT,lon,lat,RA,Dec,topRA,topDec,LST,HA,Az,El,dist)
implicit none
integer y !Year
integer m !Month
integer Day !Day
real*8 UT !UTC in hours
real*8 RA,Dec !RA and Dec of moon
! NB: Double caps are single caps in the writeup.
real*8 NN !Longitude of ascending node
real*8 i !Inclination to the ecliptic
real*8 w !Argument of perigee
real*8 a !Semi-major axis
real*8 e !Eccentricity
real*8 MM !Mean anomaly
real*8 v !True anomaly
real*8 EE !Eccentric anomaly
real*8 ecl !Obliquity of the ecliptic
real*8 d !Ephemeris time argument in days
real*8 r !Distance to sun, AU
real*8 xv,yv !x and y coords in ecliptic
real*8 lonecl,latecl !Ecliptic long and lat of moon
real*8 xg,yg,zg !Ecliptic rectangular coords
real*8 Ms !Mean anomaly of sun
real*8 ws !Argument of perihelion of sun
real*8 Ls !Mean longitude of sun (Ns=0)
real*8 Lm !Mean longitude of moon
real*8 DD !Mean elongation of moon
real*8 FF !Argument of latitude for moon
real*8 xe,ye,ze !Equatorial geocentric coords of moon
real*8 mpar !Parallax of moon (r_E / d)
real*8 lat,lon !Station coordinates on earth
real*8 gclat !Geocentric latitude
real*8 rho !Earth radius factor
real*8 GMST0,LST,HA
real*8 g
real*8 topRA,topDec !Topocentric coordinates of Moon
real*8 Az,El
real*8 dist
real*8 rad,twopi,pi,pio2
data rad/57.2957795131d0/,twopi/6.283185307d0/
d=367*y - 7*(y+(m+9)/12)/4 + 275*m/9 + Day - 730530 + UT/24.d0
ecl = 23.4393d0 - 3.563d-7 * d
! Orbital elements for Moon:
NN = 125.1228d0 - 0.0529538083d0 * d
i = 5.1454d0
w = mod(318.0634d0 + 0.1643573223d0 * d + 360000.d0,360.d0)
a = 60.2666d0
e = 0.054900d0
MM = mod(115.3654d0 + 13.0649929509d0 * d + 360000.d0,360.d0)
EE = MM + e*rad*sin(MM/rad) * (1.d0 + e*cos(MM/rad))
EE = EE - (EE - e*rad*sin(EE/rad)-MM) / (1.d0 - e*cos(EE/rad))
EE = EE - (EE - e*rad*sin(EE/rad)-MM) / (1.d0 - e*cos(EE/rad))
xv = a * (cos(EE/rad) - e)
yv = a * (sqrt(1.d0-e*e) * sin(EE/rad))
v = mod(rad*atan2(yv,xv)+720.d0,360.d0)
r = sqrt(xv*xv + yv*yv)
! Get geocentric position in ecliptic rectangular coordinates:
xg = r * (cos(NN/rad)*cos((v+w)/rad)-sin(NN/rad)*sin((v+w)/rad)*cos(i/rad))
yg = r * (sin(NN/rad)*cos((v+w)/rad)+cos(NN/rad)*sin((v+w)/rad)*cos(i/rad))
zg = r * (sin((v+w)/rad)*sin(i/rad))
! Ecliptic longitude and latitude of moon:
lonecl = mod(rad*atan2(yg/rad,xg/rad)+720.d0,360.d0)
latecl = rad*atan2(zg/rad,sqrt(xg*xg + yg*yg)/rad)
! Now include orbital perturbations:
Ms = mod(356.0470d0 + 0.9856002585d0 * d + 3600000.d0,360.d0)
ws = 282.9404d0 + 4.70935d-5*d
Ls = mod(Ms + ws + 720.d0,360.d0)
Lm = mod(MM + w + NN+720.d0,360.d0)
DD = mod(Lm - Ls + 360.d0,360.d0)
FF = mod(Lm - NN + 360.d0,360.d0)
lonecl = lonecl &
- 1.274d0 * sin((MM-2.d0*DD)/rad) &
+ 0.658d0 * sin(2.d0*DD/rad) &
- 0.186d0 * sin(Ms/rad) &
- 0.059d0 * sin((2.d0*MM-2.d0*DD)/rad) &
- 0.057d0 * sin((MM-2.d0*DD+Ms)/rad) &
+ 0.053d0 * sin((MM+2.d0*DD)/rad) &
+ 0.046d0 * sin((2.d0*DD-Ms)/rad) &
+ 0.041d0 * sin((MM-Ms)/rad) &
- 0.035d0 * sin(DD/rad) &
- 0.031d0 * sin((MM+Ms)/rad) &
- 0.015d0 * sin((2.d0*FF-2.d0*DD)/rad) &
+ 0.011d0 * sin((MM-4.d0*DD)/rad)
latecl = latecl &
- 0.173d0 * sin((FF-2.d0*DD)/rad) &
- 0.055d0 * sin((MM-FF-2.d0*DD)/rad) &
- 0.046d0 * sin((MM+FF-2.d0*DD)/rad) &
+ 0.033d0 * sin((FF+2.d0*DD)/rad) &
+ 0.017d0 * sin((2.d0*MM+FF)/rad)
r = 60.36298d0 &
- 3.27746d0*cos(MM/rad) &
- 0.57994d0*cos((MM-2.d0*DD)/rad) &
- 0.46357d0*cos(2.d0*DD/rad) &
- 0.08904d0*cos(2.d0*MM/rad) &
+ 0.03865d0*cos((2.d0*MM-2.d0*DD)/rad) &
- 0.03237d0*cos((2.d0*DD-Ms)/rad) &
- 0.02688d0*cos((MM+2.d0*DD)/rad) &
- 0.02358d0*cos((MM-2.d0*DD+Ms)/rad) &
- 0.02030d0*cos((MM-Ms)/rad) &
+ 0.01719d0*cos(DD/rad) &
+ 0.01671d0*cos((MM+Ms)/rad)
dist=r*6378.140d0
! Geocentric coordinates:
! Rectangular ecliptic coordinates of the moon:
xg = r * cos(lonecl/rad)*cos(latecl/rad)
yg = r * sin(lonecl/rad)*cos(latecl/rad)
zg = r * sin(latecl/rad)
! Rectangular equatorial coordinates of the moon:
xe = xg
ye = yg*cos(ecl/rad) - zg*sin(ecl/rad)
ze = yg*sin(ecl/rad) + zg*cos(ecl/rad)
! Right Ascension, Declination:
RA = mod(rad*atan2(ye,xe)+360.d0,360.d0)
Dec = rad*atan2(ze,sqrt(xe*xe + ye*ye))
! Now convert to topocentric system:
mpar=rad*asin(1.d0/r)
! alt_topoc = alt_geoc - mpar*cos(alt_geoc)
gclat = lat - 0.1924d0*sin(2.d0*lat/rad)
rho = 0.99883d0 + 0.00167d0*cos(2.d0*lat/rad)
GMST0 = (Ls + 180.d0)/15.d0
LST = mod(GMST0+UT+lon/15.d0+48.d0,24.d0) !LST in hours
HA = 15.d0*LST - RA !HA in degrees
g = rad*atan(tan(gclat/rad)/cos(HA/rad))
topRA = RA - mpar*rho*cos(gclat/rad)*sin(HA/rad)/cos(Dec/rad)
topDec = Dec - mpar*rho*sin(gclat/rad)*sin((g-Dec)/rad)/sin(g/rad)
HA = 15.d0*LST - topRA !HA in degrees
if(HA.gt.180.d0) HA=HA-360.d0
if(HA.lt.-180.d0) HA=HA+360.d0
pi=0.5d0*twopi
pio2=0.5d0*pi
call dcoord(pi,pio2-lat/rad,0.d0,lat/rad,ha*twopi/360,topDec/rad,az,el)
Az=az*rad
El=El*rad
return
end subroutine moon2