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source: Sophya/trunk/SophyaExt/XephemAstroLib/jupmoon.c@ 3038

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Last change on this file since 3038 was 2818, checked in by cmv, 20 years ago
Update de Xephem 3.7 cmv 21/08/2005
File size: 9.7 KB

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[2551]	1	/* jupiter moon info */
	2
	3	#include <stdio.h>
	4	#include <stdlib.h>
	5	#include <string.h>
	6	#include <math.h>
	7
	8	#include "astro.h"
	9	#include "bdl.h"
	10
	11	static int use_bdl (double jd, char *dir, MoonData md[J_NMOONS]);
	12	static void meeus_jupiter (double d, double cmlI, double cmlII,
	13	MoonData md[J_NMOONS]);
	14	static void moonradec (double jupsize, MoonData md[J_NMOONS]);
[2643]	15	static void moonSVis (Obj sop, Obj jop, MoonData md[J_NMOONS]);
[2551]	16	static void moonEVis (MoonData md[J_NMOONS]);
[2643]	17	static void moonPShad (Obj sop, Obj jop, MoonData md[J_NMOONS]);
	18	static void moonTrans (MoonData md[J_NMOONS]);
[2551]	19
	20	/* moon table and a few other goodies and when it was last computed */
	21	static double mdmjd = -123456;
	22	static MoonData jmd[J_NMOONS] = {
	23	{"Jupiter", NULL},
	24	{"Io", "I"},
	25	{"Europa", "II"},
	26	{"Ganymede", "III"},
	27	{"Callisto", "IV"}
	28	};
	29	static double sizemjd; /* size at last mjd */
	30	static double cmlImjd; /* central meridian long sys I, at last mjd */
	31	static double cmlIImjd; /* " II " */
	32
	33	/* file containing BDL coefficients */
	34	static char jbdlfn[] = "jupiter.9910";
	35
[2643]	36	/* These values are from the Explanatory Supplement.
	37	* Precession degrades them gradually over time.
	38	*/
	39	#define POLE_RA degrad(268.05) /* RA of Jupiter's north pole */
	40	#define POLE_DEC degrad(64.50) /* Dec of Jupiter's north pole */
	41
	42
[2551]	43	/* get jupiter info in md[0], moon info in md[1..J_NMOONS-1].
	44	* if !dir always use meeus model.
	45	* if !jop caller just wants md[] for names
[2643]	46	* N.B. we assume sop and jop are updated.
[2551]	47	*/
	48	void
	49	jupiter_data (
	50	double Mjd, /* mjd */
	51	char dir[], /* dir in which to look for helper files */
[2643]	52	Obj sop, / Sun */
[2551]	53	Obj jop, / jupiter */
	54	double sizep, / jup angular diam, rads */
[2643]	55	double cmlI, double cmlII, /* central meridian longitude, rads */
	56	double polera, double poledec, /* pole location */
[2551]	57	MoonData md[J_NMOONS]) /* return info */
	58	{
	59	double JD;
	60
	61	/* always copy back at least for name */
	62	memcpy (md, jmd, sizeof(jmd));
	63
[2643]	64	/* pole */
	65	if (polera) *polera = POLE_RA;
	66	if (poledec) *poledec = POLE_DEC;
	67
[2551]	68	/* nothing else if repeat call or just want names */
	69	if (Mjd == mdmjd \|\| !jop) {
	70	if (jop) {
	71	*sizep = sizemjd;
	72	*cmlI = cmlImjd;
	73	*cmlII = cmlIImjd;
	74	}
	75	return;
	76	}
	77	JD = Mjd + MJD0;
	78
	79	/* planet in [0] */
	80	md[0].ra = jop->s_ra;
	81	md[0].dec = jop->s_dec;
	82	md[0].mag = get_mag(jop);
	83	md[0].x = 0;
	84	md[0].y = 0;
	85	md[0].z = 0;
	86	md[0].evis = 1;
	87	md[0].svis = 1;
	88
	89	/* size is straight from jop */
	90	*sizep = degrad(jop->s_size/3600.0);
	91
	92	/* mags from JPL ephemeris */
	93	md[1].mag = 5.7;
	94	md[2].mag = 5.8;
	95	md[3].mag = 5.3;
	96	md[4].mag = 6.7;
	97
	98	/* get moon data from BDL if possible, else Meeus' model.
	99	* always use Meeus for cml
	100	*/
	101	if (dir && use_bdl (JD, dir, md) == 0)
	102	meeus_jupiter (Mjd, cmlI, cmlII, NULL);
	103	else
	104	meeus_jupiter (Mjd, cmlI, cmlII, md);
	105
	106	/* set visibilities */
[2643]	107	moonSVis (sop, jop, md);
	108	moonPShad (sop, jop, md);
[2551]	109	moonEVis (md);
[2643]	110	moonTrans (md);
[2551]	111
	112	/* fill in moon ra and dec */
	113	moonradec (*sizep, md);
	114
	115	/* save */
	116	mdmjd = Mjd;
	117	sizemjd = *sizep;
	118	cmlImjd = *cmlI;
	119	cmlIImjd = *cmlII;
	120	memcpy (jmd, md, sizeof(jmd));
	121	}
	122
	123	/* hunt for BDL file in dir[] and use if possible
	124	* return 0 if ok, else -1
	125	*/
	126	static int
	127	use_bdl (
	128	double JD, /* julian date */
	129	char dir[], /* directory */
	130	MoonData md[J_NMOONS]) /* fill md[1..NM-1].x/y/z for each moon */
	131	{
	132	#define JUPRAU .0004769108 /* jupiter radius, AU */
	133	double x[J_NMOONS], y[J_NMOONS], z[J_NMOONS];
	134	char buf[1024];
	135	FILE *fp;
	136	int i;
	137
	138	/* only valid 1999 through 2010 */
	139	if (JD < 2451179.50000 \|\| JD >= 2455562.5)
	140	return (-1);
	141
	142	/* open */
	143	(void) sprintf (buf, "%s/%s", dir, jbdlfn);
	144	fp = fopen (buf, "r");
	145	if (!fp)
	146	return (-1);
	147
	148	/* use it */
	149	if ((i = read_bdl (fp, JD, x, y, z, buf)) < 0) {
	150	fprintf (stderr, "%s: %s\n", jbdlfn, buf);
	151	fclose (fp);
	152	return (-1);
	153	}
	154	if (i != J_NMOONS-1) {
	155	fprintf (stderr, "%s: BDL says %d moons, code expects %d", jbdlfn,
	156	i, J_NMOONS-1);
	157	fclose (fp);
	158	return (-1);
	159	}
	160
	161	/* copy into md[1..NM-1] with our scale and sign conventions */
	162	for (i = 1; i < J_NMOONS; i++) {
	163	md[i].x = x[i-1]/JUPRAU; /* we want jup radii +E */
	164	md[i].y = -y[i-1]/JUPRAU; /* we want jup radii +S */
	165	md[i].z = -z[i-1]/JUPRAU; /* we want jup radii +front */
	166	}
	167
	168	/* ok */
	169	fclose (fp);
	170	return (0);
	171	}
	172
	173	/* compute location of GRS and Galilean moons.
	174	* if md == NULL, just to cml.
	175	* from "Astronomical Formulae for Calculators", 2nd ed, by Jean Meeus,
	176	* Willmann-Bell, Richmond, Va., U.S.A. (c) 1982, chapters 35 and 36.
	177	*/
	178	static void
	179	meeus_jupiter(
	180	double d,
	181	double cmlI, double cmlII, /* central meridian longitude, rads */
	182	MoonData md[J_NMOONS]) /* fill in md[1..NM-1].x/y/z for each moon.
	183	* N.B. md[0].ra/dec must already be set
	184	*/
	185	{
	186	#define dsin(x) sin(degrad(x))
	187	#define dcos(x) cos(degrad(x))
	188	double A, B, Del, J, K, M, N, R, V;
	189	double cor_u1, cor_u2, cor_u3, cor_u4;
	190	double solc, tmp, G, H, psi, r, r1, r2, r3, r4;
	191	double u1, u2, u3, u4;
	192	double lam, Ds;
	193	double z1, z2, z3, z4;
	194	double De, dsinDe;
	195	double theta, phi;
	196	double tvc, pvc;
	197	double salpha, calpha;
	198	int i;
	199
	200	V = 134.63 + 0.00111587 * d;
	201
	202	M = (358.47583 + 0.98560003*d);
	203	N = (225.32833 + 0.0830853d) + 0.33 dsin (V);
	204
	205	J = 221.647 + 0.9025179d - 0.33 dsin(V);
	206
	207	A = 1.916dsin(M) + 0.02dsin(2*M);
	208	B = 5.552dsin(N) + 0.167dsin(2*N);
	209	K = (J+A-B);
	210	R = 1.00014 - 0.01672 * dcos(M) - 0.00014 * dcos(2*M);
	211	r = 5.20867 - 0.25192 * dcos(N) - 0.00610 * dcos(2*N);
	212	Del = sqrt (RR + rr - 2Rr*dcos(K));
	213	psi = raddeg (asin (R/Del*dsin(K)));
	214
	215	cmlI = degrad(268.28 + 877.8169088(d - Del/173) + psi - B);
	216	range (cmlI, 2*PI);
	217	cmlII = degrad(290.28 + 870.1869088(d - Del/173) + psi - B);
	218	range (cmlII, 2*PI);
	219
	220	/* that's it if don't want moon info too */
	221	if (!md)
	222	return;
	223
	224	solc = (d - Del/173.); /* speed of light correction */
	225	tmp = psi - B;
	226
	227	u1 = 84.5506 + 203.4058630 * solc + tmp;
	228	u2 = 41.5015 + 101.2916323 * solc + tmp;
	229	u3 = 109.9770 + 50.2345169 * solc + tmp;
	230	u4 = 176.3586 + 21.4879802 * solc + tmp;
	231
	232	G = 187.3 + 50.310674 * solc;
	233	H = 311.1 + 21.569229 * solc;
	234
	235	cor_u1 = 0.472 * dsin (2*(u1-u2));
	236	cor_u2 = 1.073 * dsin (2*(u2-u3));
	237	cor_u3 = 0.174 * dsin (G);
	238	cor_u4 = 0.845 * dsin (H);
	239
	240	r1 = 5.9061 - 0.0244 * dcos (2*(u1-u2));
	241	r2 = 9.3972 - 0.0889 * dcos (2*(u2-u3));
	242	r3 = 14.9894 - 0.0227 * dcos (G);
	243	r4 = 26.3649 - 0.1944 * dcos (H);
	244
	245	md[1].x = -r1 * dsin (u1+cor_u1);
	246	md[2].x = -r2 * dsin (u2+cor_u2);
	247	md[3].x = -r3 * dsin (u3+cor_u3);
	248	md[4].x = -r4 * dsin (u4+cor_u4);
	249
	250	lam = 238.05 + 0.083091d + 0.33dsin(V) + B;
	251	Ds = 3.07*dsin(lam + 44.5);
	252	De = Ds - 2.15dsin(psi)dcos(lam+24.)
	253	- 1.31(r-Del)/Deldsin(lam-99.4);
	254	dsinDe = dsin(De);
	255
	256	z1 = r1 * dcos(u1+cor_u1);
	257	z2 = r2 * dcos(u2+cor_u2);
	258	z3 = r3 * dcos(u3+cor_u3);
	259	z4 = r4 * dcos(u4+cor_u4);
	260
	261	md[1].y = z1*dsinDe;
	262	md[2].y = z2*dsinDe;
	263	md[3].y = z3*dsinDe;
	264	md[4].y = z4*dsinDe;
	265
	266	/* compute sky transformation angle as triple vector product */
	267	tvc = PI/2.0 - md[0].dec;
	268	pvc = md[0].ra;
	269	theta = PI/2.0 - POLE_DEC;
	270	phi = POLE_RA;
	271	salpha = -sin(tvc)sin(theta)(cos(pvc)sin(phi) - sin(pvc)cos(phi));
	272	calpha = sqrt (1.0 - salpha*salpha);
	273
	274	for (i = 0; i < J_NMOONS; i++) {
	275	double tx = md[i].xcalpha + md[i].ysalpha;
	276	double ty = -md[i].xsalpha + md[i].ycalpha;
	277	md[i].x = tx;
	278	md[i].y = ty;
	279	}
	280
	281	md[1].z = z1;
	282	md[2].z = z2;
	283	md[3].z = z3;
	284	md[4].z = z4;
	285	}
	286
	287
	288	/* given jupiter loc in md[0].ra/dec and size, and location of each moon in
	289	* md[1..NM-1].x/y in jup radii, find ra/dec of each moon in md[1..NM-1].ra/dec.
	290	*/
	291	static void
	292	moonradec (
	293	double jupsize, /* jup diameter, rads */
	294	MoonData md[J_NMOONS]) /* fill in RA and Dec */
	295	{
	296	double juprad = jupsize/2;
	297	double jupra = md[0].ra;
	298	double jupdec = md[0].dec;
	299	int i;
	300
	301	for (i = 1; i < J_NMOONS; i++) {
	302	double dra = juprad * md[i].x;
	303	double ddec = juprad * md[i].y;
	304	md[i].ra = jupra + dra;
	305	md[i].dec = jupdec - ddec;
	306	}
	307	}
	308
	309	/* set svis according to whether moon is in sun light */
	310	static void
	311	moonSVis(
[2643]	312	Obj sop, / SUN */
[2551]	313	Obj jop, / jupiter */
	314	MoonData md[J_NMOONS])
	315	{
[2643]	316	double esd = sop->s_edist;
[2551]	317	double eod = jop->s_edist;
	318	double sod = jop->s_sdist;
	319	double soa = degrad(jop->s_elong);
	320	double esa = asin(esd*sin(soa)/sod);
	321	double h = sod*jop->s_hlat;
	322	double nod = h*(1./eod - 1./sod);
	323	double sca = cos(esa), ssa = sin(esa);
	324	int i;
	325
	326	for (i = 1; i < J_NMOONS; i++) {
	327	MoonData *mdp = &md[i];
	328	double xp = scamdp->x + ssamdp->z;
	329	double yp = mdp->y;
	330	double zp = -ssamdp->x + scamdp->z;
	331	double ca = cos(nod), sa = sin(nod);
	332	double xpp = xp;
	333	double ypp = cayp - sazp;
	334	double zpp = sayp + cazp;
	335	int outside = xppxpp + yppypp > 1.0;
	336	int infront = zpp > 0.0;
	337	mdp->svis = outside \|\| infront;
	338	}
	339	}
	340
	341	/* set evis according to whether moon is geometrically visible from earth */
	342	static void
	343	moonEVis (MoonData md[J_NMOONS])
	344	{
	345	int i;
	346
	347	for (i = 1; i < J_NMOONS; i++) {
	348	MoonData *mdp = &md[i];
	349	int outside = mdp->xmdp->x + mdp->ymdp->y > 1.0;
	350	int infront = mdp->z > 0.0;
	351	mdp->evis = outside \|\| infront;
	352	}
	353	}
	354
[2643]	355	/* set pshad and sx,sy shadow info */
	356	static void
	357	moonPShad(
	358	Obj sop, / SUN */
	359	Obj jop, / jupiter */
	360	MoonData md[J_NMOONS])
	361	{
	362	int i;
	363
	364	for (i = 1; i < J_NMOONS; i++) {
	365	MoonData *mdp = &md[i];
	366	mdp->pshad = !plshadow (jop, sop, POLE_RA, POLE_DEC, mdp->x,
	367	mdp->y, mdp->z, &mdp->sx, &mdp->sy);
	368	}
	369	}
	370
	371	/* set whether moons are transiting */
	372	static void
	373	moonTrans (MoonData md[J_NMOONS])
	374	{
	375	int i;
	376
	377	for (i = 1; i < J_NMOONS; i++) {
	378	MoonData *mdp = &md[i];
	379	mdp->trans = mdp->z > 0 && mdp->xmdp->x + mdp->ymdp->y < 1;
	380	}
	381	}
	382
[2551]	383	/* For RCS Only -- Do Not Edit */
[2818]	384	static char rcsid[2] = {(char )rcsid, "@(#) $RCSfile: jupmoon.c,v $ $Date: 2005-08-21 10:02:37 $ $Revision: 1.3 $ $Name: not supported by cvs2svn $"};

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