plan9port/src/cmd/astro/venus.c

#include "astro.h"


void
venus(void)
{
	double pturbl, pturbb, pturbr;
	double lograd;
	double dele, enom, vnom, nd, sl;
	double v0, t0, m0, j0, s0;
	double lsun, elong, ci, dlong;

/*
 *	here are the mean orbital elements
 */

	ecc = .00682069 - .00004774*capt + 0.091e-6*capt2;
	incl = 3.393631 + .0010058*capt - 0.97e-6*capt2;
	node = 75.779647 + .89985*capt + .00041*capt2;
	argp = 130.163833 + 1.408036*capt - .0009763*capt2;
	mrad = .7233316;
	anom = 212.603219 + 1.6021301540*eday + .00128605*capt2;
	motion = 1.6021687039;

/*
 *	mean anomalies of perturbing planets
 */

	v0 = 212.60 + 1.602130154*eday;
	t0 = 358.63  + .985608747*eday;
	m0 = 319.74 + 0.524032490*eday;
	j0 = 225.43 + .083090842*eday;
	s0 = 175.8  + .033459258*eday;

	v0 *= radian;
	t0 *= radian;
	m0 *= radian;
	j0 *= radian;
	s0 *= radian;

	incl *= radian;
	node *= radian;
	argp *= radian;
	anom = fmod(anom, 360.)*radian;

/*
 *	computation of long period terms affecting the mean anomaly
 */

	anom +=
		   (2.761-0.022*capt)*radsec*sin(
		  13.*t0 - 8.*v0 + 43.83*radian + 4.52*radian*capt)
		 + 0.268*radsec*cos(4.*m0 - 7.*t0 + 3.*v0)
		 + 0.019*radsec*sin(4.*m0 - 7.*t0 + 3.*v0)
		 - 0.208*radsec*sin(s0 + 1.4*radian*capt);

/*
 *	computation of elliptic orbit
 */

	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;

/*
 *	perturbations in longitude
 */

	icosadd(venfp, vencp);
	pturbl = cosadd(4, v0, t0, m0, j0);
	pturbl *= radsec;

/*
 *	perturbations in latidude
 */

	pturbb = cosadd(3, v0, t0, j0);
	pturbb *= radsec;

/*
 *	perturbations in log radius vector
 */

	pturbr = cosadd(4, v0, t0, m0, j0);

/*
 *	reduction to the ecliptic
 */

	lambda += pturbl;
	nd = lambda - node;
	lambda = node + atan2(sin(nd)*cos(incl),cos(nd));

	sl = sin(incl)*sin(nd);
	beta = atan2(sl, pyth(sl)) + pturbb;

	lograd = pturbr*2.30258509;
	rad *= 1 + lograd;


	motion *= radian*mrad*mrad/(rad*rad);

/*
 *	computation of magnitude
 */

	lsun = 99.696678 + 0.9856473354*eday;
	lsun *= radian;
	elong = lambda - lsun;
	ci = (rad - cos(elong))/sqrt(1 + rad*rad - 2*rad*cos(elong));
	dlong = atan2(pyth(ci), ci)/radian;
	mag = -4 + .01322*dlong + .0000004247*dlong*dlong*dlong;

	semi = 8.41;

	helio();
	geo();
}
Astro with some minor changes to placate Unix. 2004-04-21 02:16:43 +00:00			`#include "astro.h"`


			`void`
			`venus(void)`
			`{`
			`double pturbl, pturbb, pturbr;`
			`double lograd;`
			`double dele, enom, vnom, nd, sl;`
			`double v0, t0, m0, j0, s0;`
			`double lsun, elong, ci, dlong;`

			`/*`
			`* here are the mean orbital elements`
			`*/`

			`ecc = .00682069 - .00004774capt + 0.091e-6capt2;`
			`incl = 3.393631 + .0010058capt - 0.97e-6capt2;`
			`node = 75.779647 + .89985capt + .00041capt2;`
			`argp = 130.163833 + 1.408036capt - .0009763capt2;`
			`mrad = .7233316;`
			`anom = 212.603219 + 1.6021301540eday + .00128605capt2;`
			`motion = 1.6021687039;`

			`/*`
			`* mean anomalies of perturbing planets`
			`*/`

			`v0 = 212.60 + 1.602130154*eday;`
			`t0 = 358.63 + .985608747*eday;`
			`m0 = 319.74 + 0.524032490*eday;`
			`j0 = 225.43 + .083090842*eday;`
			`s0 = 175.8 + .033459258*eday;`

			`v0 *= radian;`
			`t0 *= radian;`
			`m0 *= radian;`
			`j0 *= radian;`
			`s0 *= radian;`

			`incl *= radian;`
			`node *= radian;`
			`argp *= radian;`
			`anom = fmod(anom, 360.)*radian;`

			`/*`
			`* computation of long period terms affecting the mean anomaly`
			`*/`

			`anom +=`
			`(2.761-0.022capt)radsec*sin(`
			`13.t0 - 8.v0 + 43.83radian + 4.52radian*capt)`
			`+ 0.268radseccos(4.m0 - 7.t0 + 3.*v0)`
			`+ 0.019radsecsin(4.m0 - 7.t0 + 3.*v0)`
			`- 0.208radsecsin(s0 + 1.4radiancapt);`

			`/*`
			`* computation of elliptic orbit`
			`*/`

			`enom = anom + ecc*sin(anom);`
			`do {`
			`dele = (anom - enom + ecc * sin(enom)) /`
			`(1 - ecc*cos(enom));`
			`enom += dele;`
			`} while(fabs(dele) > converge);`
			`vnom = 2atan2(sqrt((1+ecc)/(1-ecc))sin(enom/2),`
			`cos(enom/2));`
			`rad = mrad(1 - ecccos(enom));`

			`lambda = vnom + argp;`

			`/*`
			`* perturbations in longitude`
			`*/`

			`icosadd(venfp, vencp);`
			`pturbl = cosadd(4, v0, t0, m0, j0);`
			`pturbl *= radsec;`

			`/*`
			`* perturbations in latidude`
			`*/`

			`pturbb = cosadd(3, v0, t0, j0);`
			`pturbb *= radsec;`

			`/*`
			`* perturbations in log radius vector`
			`*/`

			`pturbr = cosadd(4, v0, t0, m0, j0);`

			`/*`
			`* reduction to the ecliptic`
			`*/`

			`lambda += pturbl;`
			`nd = lambda - node;`
			`lambda = node + atan2(sin(nd)*cos(incl),cos(nd));`

			`sl = sin(incl)*sin(nd);`
			`beta = atan2(sl, pyth(sl)) + pturbb;`

			`lograd = pturbr*2.30258509;`
			`rad *= 1 + lograd;`


			`motion = radianmradmrad/(radrad);`

			`/*`
			`* computation of magnitude`
			`*/`

			`lsun = 99.696678 + 0.9856473354*eday;`
			`lsun *= radian;`
			`elong = lambda - lsun;`
			`ci = (rad - cos(elong))/sqrt(1 + radrad - 2rad*cos(elong));`
			`dlong = atan2(pyth(ci), ci)/radian;`
			`mag = -4 + .01322dlong + .0000004247dlongdlongdlong;`

			`semi = 8.41;`

			`helio();`
			`geo();`
			`}`