| #include "astro.h" |
| |
| static double elem[] = |
| { |
| 36525.0, /* [0] eday of epoc */ |
| |
| 39.48168677, /* [1] semi major axis (au) */ |
| 0.24880766, /* [2] eccentricity */ |
| 17.14175, /* [3] inclination (deg) */ |
| 110.30347, /* [4] longitude of the ascending node (deg) */ |
| 224.06676, /* [5] longitude of perihelion (deg) */ |
| 238.92881, /* [6] mean longitude (deg) */ |
| |
| -0.00076912, /* [1+6] (au/julian century) */ |
| 0.00006465, /* [2+6] (e/julian century) */ |
| 11.07, /* [3+6] (arcsec/julian century) */ |
| -37.33, /* [4+6] (arcsec/julian century) */ |
| -132.25, /* [5+6] (arcsec/julian century) */ |
| 522747.90, /* [6+6] (arcsec/julian century) */ |
| }; |
| |
| void |
| plut(void) |
| { |
| double pturbl, pturbb, pturbr; |
| double lograd; |
| double dele, enom, vnom, nd, sl; |
| |
| double capj, capn, eye, comg, omg; |
| double sb, su, cu, u, b, up; |
| double sd, ca, sa; |
| |
| double cy; |
| |
| cy = (eday - elem[0]) / 36525.; /* per julian century */ |
| |
| mrad = elem[1] + elem[1+6]*cy; |
| ecc = elem[2] + elem[2+6]*cy; |
| |
| cy = cy / 3600; /* arcsec/deg per julian century */ |
| incl = elem[3] + elem[3+6]*cy; |
| node = elem[4] + elem[4+6]*cy; |
| argp = elem[5] + elem[5+6]*cy; |
| |
| anom = elem[6] + elem[6+6]*cy - argp; |
| motion = elem[6+6] / 36525. / 3600; |
| |
| incl *= radian; |
| node *= radian; |
| argp *= radian; |
| anom = fmod(anom,360.)*radian; |
| |
| enom = anom + ecc*sin(anom); |
| do { |
| dele = (anom - enom + ecc * sin(enom)) / |
| (1. - ecc*cos(enom)); |
| enom += dele; |
| } while(fabs(dele) > converge); |
| vnom = 2.*atan2(sqrt((1.+ecc)/(1.-ecc))*sin(enom/2.), |
| cos(enom/2.)); |
| rad = mrad*(1. - ecc*cos(enom)); |
| |
| lambda = vnom + argp; |
| pturbl = 0.; |
| lambda += pturbl*radsec; |
| pturbb = 0.; |
| pturbr = 0.; |
| |
| /* |
| * reduce to the ecliptic |
| */ |
| |
| nd = lambda - node; |
| lambda = node + atan2(sin(nd)*cos(incl),cos(nd)); |
| |
| sl = sin(incl)*sin(nd) + pturbb*radsec; |
| beta = atan2(sl, pyth(sl)); |
| |
| lograd = pturbr*2.30258509; |
| rad *= 1. + lograd; |
| |
| |
| lambda -= 1185.*radsec; |
| beta -= 51.*radsec; |
| |
| motion *= radian*mrad*mrad/(rad*rad); |
| semi = 83.33; |
| |
| /* |
| * here begins the computation of magnitude |
| * first find the geocentric equatorial coordinates of Saturn |
| */ |
| |
| sd = rad*(cos(beta)*sin(lambda)*sin(obliq) + |
| sin(beta)*cos(obliq)); |
| sa = rad*(cos(beta)*sin(lambda)*cos(obliq) - |
| sin(beta)*sin(obliq)); |
| ca = rad*cos(beta)*cos(lambda); |
| sd += zms; |
| sa += yms; |
| ca += xms; |
| alpha = atan2(sa,ca); |
| delta = atan2(sd,sqrt(sa*sa+ca*ca)); |
| |
| /* |
| * here are the necessary elements of Saturn's rings |
| * cf. Exp. Supp. p. 363ff. |
| */ |
| |
| capj = 6.9056 - 0.4322*capt; |
| capn = 126.3615 + 3.9894*capt + 0.2403*capt2; |
| eye = 28.0743 - 0.0128*capt; |
| comg = 168.1179 + 1.3936*capt; |
| omg = 42.9236 - 2.7390*capt - 0.2344*capt2; |
| |
| capj *= radian; |
| capn *= radian; |
| eye *= radian; |
| comg *= radian; |
| omg *= radian; |
| |
| /* |
| * now find saturnicentric ring-plane coords of the earth |
| */ |
| |
| sb = sin(capj)*cos(delta)*sin(alpha-capn) - |
| cos(capj)*sin(delta); |
| su = cos(capj)*cos(delta)*sin(alpha-capn) + |
| sin(capj)*sin(delta); |
| cu = cos(delta)*cos(alpha-capn); |
| u = atan2(su,cu); |
| b = atan2(sb,sqrt(su*su+cu*cu)); |
| |
| /* |
| * and then the saturnicentric ring-plane coords of the sun |
| */ |
| |
| su = sin(eye)*sin(beta) + |
| cos(eye)*cos(beta)*sin(lambda-comg); |
| cu = cos(beta)*cos(lambda-comg); |
| up = atan2(su,cu); |
| |
| /* |
| * at last, the magnitude |
| */ |
| |
| |
| sb = sin(b); |
| mag = -8.68 +2.52*fabs(up+omg-u)- |
| 2.60*fabs(sb) + 1.25*(sb*sb); |
| |
| helio(); |
| geo(); |
| } |