/**************************************************************************** pom.c Phase of the Moon. Calculates the current phase of the moon. Based on routines from `Practical Astronomy with Your Calculator', by Duffett-Smith. Comments give the section from the book that particular piece of code was adapted from. -- Keith E. Brandt VIII 1984 ****************************************************************************/ #include #include #include #define PI 3.141592654 #define EPOCH 1983 #define EPSILONg 279.103035 /* solar ecliptic long at EPOCH */ #define RHOg 282.648015 /* solar ecliptic long of perigee at EPOCH */ #define e 0.01671626 /* solar orbit eccentricity */ #define lzero 106.306091 /* lunar mean long at EPOCH */ #define Pzero 111.481526 /* lunar mean long of perigee at EPOCH */ #define Nzero 93.913033 /* lunar mean long of node at EPOCH */ main() { double dtor(); double adj360(); double potm(); int i_phase; long * calloc(); long *lo = calloc (1, sizeof(long)); /* used by time calls */ struct tm *pt; /* ptr to time structure */ double days; /* days since EPOCH */ double phase; /* percent of lunar surface illuminated */ double phase2; /* percent of lunar surface illuminated one day later */ int i = EPOCH; time (lo); /* get system time */ pt = gmtime(lo); /* get ptr to gmt time struct */ /* calculate days since EPOCH */ days = (pt->tm_yday +1) + ((pt->tm_hour + (pt->tm_min / 60.0) + (pt->tm_sec / 3600.0)) / 24.0); while (i < pt->tm_year + 1900) days = days + 365 + ly(i++); phase = potm(days); printf("The Moon is "); i_phase = phase + 0.5; if (i_phase == 100) { printf("Full\n"); } else { if (i_phase == 0) printf("New\n"); else { if (i_phase == 50) { phase2 = potm(++days); if (phase2 > phase) printf("at the First Quarter\n"); else printf("at the Last Quarter\n"); } else { if (i_phase > 50) { phase2 = potm(++days); if (phase2 > phase) printf("Waxing "); else printf("Waning "); printf("Gibbous (%1.0f%% of Full)\n", phase); } else { if (i_phase < 50) { phase2 = potm(++days); if (phase2 > phase) printf("Waxing "); else printf("Waning "); printf("Crescent (%1.0f%% of Full)\n", phase); } } } } } } double potm(days) double days; { double N; double Msol; double Ec; double LambdaSol; double l; double Mm; double Ev; double Ac; double A3; double Mmprime; double A4; double lprime; double V; double ldprime; double D; double Nm; N = 360 * days / 365.2422; /* sec 42 #3 */ adj360(&N); Msol = N + EPSILONg - RHOg; /* sec 42 #4 */ adj360(&Msol); Ec = 360 / PI * e * sin(dtor(Msol)); /* sec 42 #5 */ LambdaSol = N + Ec + EPSILONg; /* sec 42 #6 */ adj360(&LambdaSol); l = 13.1763966 * days + lzero; /* sec 61 #4 */ adj360(&l); Mm = l - (0.1114041 * days) - Pzero; /* sec 61 #5 */ adj360(&Mm); Nm = Nzero - (0.0529539 * days); /* sec 61 #6 */ adj360(&Nm); Ev = 1.2739 * sin(dtor(2*(l - LambdaSol) - Mm)); /* sec 61 #7 */ Ac = 0.1858 * sin(dtor(Msol)); /* sec 61 #8 */ A3 = 0.37 * sin(dtor(Msol)); Mmprime = Mm + Ev - Ac - A3; /* sec 61 #9 */ Ec = 6.2886 * sin(dtor(Mmprime)); /* sec 61 #10 */ A4 = 0.214 * sin(dtor(2 * Mmprime)); /* sec 61 #11 */ lprime = l + Ev + Ec - Ac + A4; /* sec 61 #12 */ V = 0.6583 * sin(dtor(2 * (lprime - LambdaSol))); /* sec 61 #13 */ ldprime = lprime + V; /* sec 61 #14 */ D = ldprime - LambdaSol; /* sec 63 #2 */ return (50 * (1 - cos(dtor(D)))); /* sec 63 #3 */ } ly(yr) int yr; { /* returns 1 if leapyear, 0 otherwise */ return (yr % 4 == 0 && yr % 100 != 0 || yr % 400 == 0); } double dtor(deg) double deg; { /* convert degrees to radians */ return (deg * PI / 180); } double adj360(deg) double *deg; { /* adjust value so 0 <= deg <= 360 */ do if (*deg < 0) *deg += 360; else if (*deg > 360) *deg -= 360; while (*deg < 0 || *deg > 360); }