src/gen/sun.c

/* Copyright (c) 1989 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 *           SOLAR CALCULATIONS
 *
 *               3/31/87
 *
 */

#define  PI  3.141592654

double  s_latitude = 0.66;      /* site latitude (radians) */
double  s_longitude = 2.13;     /* site longitude (radians) */
double  s_meridian = 2.0944;    /* standard meridian (radians) */


int
jdate(month, day)               /* Julian date (days into year) */
int  month, day;
{
        static short  mo_da[12] = {0,31,59,90,120,151,181,212,243,273,304,334};
        
        return(mo_da[month-1] + day);
}


double
stadj(jd)               /* solar time adjustment from Julian date */
int  jd;
{
        double  sin();

        return( 0.170 * sin( (4*PI/373) * (jd - 80) ) -
                0.129 * sin( (2*PI/355) * (jd - 8) ) +
                12 * (s_meridian - s_longitude) / PI );
}


double
sdec(jd)                /* solar declination angle from Julian date */
int  jd;
{
        double  sin();

        return( 0.4093 * sin( (2*PI/368) * (jd - 81) ) );
}


double
salt(sd, st)    /* solar altitude from solar declination and solar time */
double  sd, st;
{
        double  sin(), cos(), asin();

        return( asin( sin(s_latitude) * sin(sd) -
                        cos(s_latitude) * cos(sd) * cos(st*(PI/12)) ) );
}


double
sazi(sd, st)    /* solar azimuth from solar declination and solar time */
double  sd, st;
{
        double  sin(), cos(), atan2();

        return( -atan2( cos(sd)*sin(st*(PI/12)),
                        -cos(s_latitude)*sin(sd) -
                        sin(s_latitude)*cos(sd)*cos(st*(PI/12)) ) );
}
Revision:	2.1
Committed:	Tue Nov 12 17:04:42 1991 UTC (33 years, 11 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 1.2:	+0 -0 lines
Log Message:	updated revision number for release 2.0
#	User	Rev	Content
1	greg	1.2	/* Copyright (c) 1989 Regents of the University of California */
2	greg	1.1
3			#ifndef lint
4			static char SCCSid[] = "$SunId$ LBL";
5			#endif
6	greg	1.2
7			/*
8	greg	1.1	* SOLAR CALCULATIONS
9			*
10			* 3/31/87
11			*
12			*/
13
14			#define PI 3.141592654
15
16			double s_latitude = 0.66; /* site latitude (radians) */
17			double s_longitude = 2.13; /* site longitude (radians) */
18			double s_meridian = 2.0944; /* standard meridian (radians) */
19
20
21			int
22			jdate(month, day) /* Julian date (days into year) */
23			int month, day;
24			{
25			static short mo_da[12] = {0,31,59,90,120,151,181,212,243,273,304,334};
26
27			return(mo_da[month-1] + day);
28			}
29
30
31			double
32			stadj(jd) /* solar time adjustment from Julian date */
33			int jd;
34			{
35			double sin();
36
37			return( 0.170 * sin( (4PI/373) (jd - 80) ) -
38			0.129 * sin( (2PI/355) (jd - 8) ) +
39			12 * (s_meridian - s_longitude) / PI );
40			}
41
42
43			double
44			sdec(jd) /* solar declination angle from Julian date */
45			int jd;
46			{
47			double sin();
48
49			return( 0.4093 * sin( (2PI/368) (jd - 81) ) );
50			}
51
52
53			double
54			salt(sd, st) /* solar altitude from solar declination and solar time */
55			double sd, st;
56			{
57			double sin(), cos(), asin();
58
59			return( asin( sin(s_latitude) * sin(sd) -
60			cos(s_latitude) * cos(sd) * cos(st*(PI/12)) ) );
61			}
62
63
64			double
65			sazi(sd, st) /* solar azimuth from solar declination and solar time */
66			double sd, st;
67			{
68			double sin(), cos(), atan2();
69
70			return( -atan2( cos(sd)sin(st(PI/12)),
71			-cos(s_latitude)*sin(sd) -
72			sin(s_latitude)cos(sd)cos(st*(PI/12)) ) );
73			}