def approx_moment_of_depression(self, tee, alpha, early):
"""Return the moment in local time near tee when depression angle
of sun is alpha (negative if above horizon) at location;
early is true when MORNING event is sought and false for EVENING.
Raise VlueError if depression angle is not reached."""
ttry = self.sine_offset(tee, alpha)
date = Clock.fixed_from_moment(tee)
if alpha >= 0:
if early:
alt = date
else:
alt = date + 1
else:
alt = date + Clock.days_from_hours(12)
if abs(ttry) > 1:
value = self.sine_offset(alt, alpha)
else:
value = ttry
if abs(value) <= 1:
temp = -1 if early else 1
temp *= mod(Clock.days_from_hours(12) + arcsin_degrees(value) / 360, 1) - Clock.days_from_hours(6)
temp += date + Clock.days_from_hours(12)
return self.local_from_apparent(temp)
else:
raise ValueError("Depression angle not reached")
def location(cls, tee):
"""Return location of Beijing; time zone varies with time, tee."""
year = GregorianDate.to_year(ifloor(tee))
if (year < 1929):
return Location(angle(39, 55, 0), angle(116, 25, 0), 43.5, Clock.days_from_hours(1397/180))
else:
return Location(angle(39, 55, 0), angle(116, 25, 0), 43.5, Clock.days_from_hours(8))
def japanese_location(tee):
"""Return the location for Japanese calendar; varies with moment, tee."""
year = GregorianDate.to_year(ifloor(tee))
if (year < 1888):
# Tokyo (139 deg 46 min east) local time
loc = Location(mpf(35.7), angle(139, 46, 0), 24, Clock.days_from_hours(9 + 143/450))
else:
# Longitude 135 time zone
loc = Location(35, 135, 0, Clock.days_from_hours(9))
return loc
def molad(cls, month, year):
"""Return moment of mean conjunction of month in Hebrew year."""
y = year + 1 if month < HebrewMonth.TISHRI else year
months_elapsed = month - HebrewMonth.TISHRI + quotient(235 * y - 234, 19)
return (
cls.EPOCH - Fraction(876, 25920) + months_elapsed * (29 + Clock.days_from_hours(12) + Fraction(793, 25920))
)
def from_fixed(cls, date):
"""Return Old Hindu solar date equivalent to fixed date date."""
sun = cls.hindu_day_count(date) + Clock.days_from_hours(6)
year = quotient(sun, cls.ARYA_SOLAR_YEAR)
month = mod(quotient(sun, cls.ARYA_SOLAR_MONTH), 12) + 1
day = ifloor(mod(sun, cls.ARYA_SOLAR_MONTH)) + 1
return OldHinduSolarDate(year, month, day)
def sunset(cls, date):
"""Return sunset at HINDU_LOCATION on date, date."""
return (date + Clock.days_from_hours(18) +
((cls.UJJAIN.longitude - cls.LOCATION.longitude) / 360) -
cls.equation_of_time(date) +
(((1577917828/1582237828) / 360) *
(- cls.ascensional_difference(date, cls.LOCATION) +
(3/4 * cls.solar_sidereal_difference(date)))))
def sunrise(cls, date):
"""Return the sunrise at hindu_location on date, date."""
return (date + Clock.days_from_hours(6) +
((cls.UJJAIN.longitude - cls.LOCATION.longitude) / 360) -
cls.equation_of_time(date) +
((1577917828/1582237828 / 360) *
(cls.ascensional_difference(date, cls.LOCATION) +
(1/4 * cls.solar_sidereal_difference(date)))))
def vietnamese_location(tee):
"""Return the location for Vietnamese calendar is Hanoi;
varies with moment, tee. Time zone has changed over the years."""
if (tee < GregorianDate.new_year(1968)):
z = 8
else:
z =7
return Location(angle(21, 2, 0), angle(105, 51, 0), 12, Clock.days_from_hours(z))
def sundial_time(cls, tee):
"""Return Hindu local time of temporal moment, tee."""
date = Clock.fixed_from_moment(tee)
time = mod(tee, 1)
q = ifloor(4 * time)
if q == 0:
a = cls.sunset(date - 1)
b = cls.sunrise(date)
t = Clock.days_from_hours(-6)
elif q == 3:
a = cls.sunset(date)
b = cls.sunrise(date + 1)
t = Clock.days_from_hours(18)
else:
a = cls.sunrise(date)
b = cls.sunset(date)
t = Clock.days_from_hours(6)
return a + (2 * (b - a) * (time - t))
def to_fixed(self):
"""Return the fixed date of this Hindu lunar date."""
approx = OldHindu.EPOCH + (self.SIDEREAL_YEAR * (self.year + self.LUNAR_ERA + ((self.month - 1) / 12)))
s = ifloor(approx - ((1/360) * self.SIDEREAL_YEAR * mod(self.hindu_solar_longitude(approx) - ((self.month - 1) * 30) + 180, 360) - 180))
k = self.lunar_day_from_moment(s + Clock.days_from_hours(6))
if (3 < k < 27):
temp = k
else:
mid = self.lunar_from_fixed(s - 15)
if ((mid.month != self.month) or
(mid.leap_month and not self.leap_month)):
temp = mod(k + 15, 30) - 15
else:
temp = mod(k - 15, 30) + 15
est = s + self.day - temp
tau = est - mod(self.lunar_day_from_moment(est + Clock.days_from_hours(6)) - self.day + 15, 30) + 15
date = next_int(tau - 1, lambda d: self.lunar_day_from_moment(self.sunrise(d)) in [self.day, amod(self.day + 1, 30)])
return date + 1 if self.leap_day else date
def moment_of_depression(self, approx, alpha, early):
"""Return the moment in local time near approx when depression
angle of sun is alpha (negative if above horizon) at location;
early is true when MORNING event is sought, and false for EVENING."""
tee = self.approx_moment_of_depression(approx, alpha, early)
if abs(approx - tee) < Clock.days_from_seconds(30):
return tee
else:
return self.moment_of_depression(tee, alpha, early)
def from_fixed(cls, fixed_date):
"""Return Old Hindu lunar date equivalent to fixed date 'fixed_date'."""
sun = cls.hindu_day_count(fixed_date) + Clock.days_from_hours(6)
new_moon = sun - mod(sun, cls.ARYA_LUNAR_MONTH)
leap = cls.ARYA_SOLAR_MONTH - cls.ARYA_LUNAR_MONTH >= mod(new_moon, cls.ARYA_SOLAR_MONTH) and mod(new_moon, cls.ARYA_SOLAR_MONTH) > 0
month = mod(iceiling(new_moon / cls.ARYA_SOLAR_MONTH), 12) + 1
day = mod(quotient(sun, cls.ARYA_LUNAR_DAY), 30) + 1
year = iceiling((new_moon + cls.ARYA_SOLAR_MONTH) / cls.ARYA_SOLAR_YEAR) - 1
return OldHinduLunarDate(year, month, leap, day)
def hindu_tithi_occur(l_month, tithi, tee, l_year):
"""Return the fixed date of occurrence of Hindu lunar tithi prior
to sundial time, tee, in Hindu lunar month, l_month, and
year, l_year."""
approx = hindu_date_occur(l_month, ifloor(tithi), l_year)
lunar = HinduLunarDate.day_at_or_after(tithi, approx - 2)
ttry = Clock.fixed_from_moment(lunar)
tee_h = HinduLunarDate.UJJAIN.standard_from_sundial(ttry + tee)
if lunar <= tee_h or HinduLunarDate.lunar_phase(HinduLunarDate.UJJAIN.standard_from_sundial(ttry + 1 + tee)) > 12 * tithi:
return ttry
else:
return ttry + 1
def moonrise(self, date):
"""Return the standard time of moonrise on fixed, date,
and location, location."""
t = self.universal_from_standard(date)
waning = (Lunar.lunar_phase(t) > 180)
alt = self.observed_lunar_altitude(t)
offset = alt / 360
if waning and (offset > 0):
approx = t + 1 - offset
elif waning:
approx = t - offset
else:
approx = t + (1 / 2) + offset
rise = binary_search(approx - Clock.days_from_hours(3),
approx + Clock.days_from_hours(3),
lambda u, l: ((u - l) < Clock.days_from_hours(1/60)),
lambda x: self.observed_lunar_altitude(x) > 0)
if rise < (t + 1):
return self.standard_from_universal(rise)
raise ValueError()
def to_fixed(self):
"""Return the fixed date corresponding to Hindu lunar date, l_date."""
approx = (OldHindu.EPOCH + self.MEAN_SIDEREAL_YEAR * (self.year + self.LUNAR_ERA + ((self.month - 1) / 12)))
s = ifloor(approx -
1/360 * self.MEAN_SIDEREAL_YEAR *
(mod(sidereal_solar_longitude(approx) -
(self.month - 1) * 30 + 180, 360) - 180))
k = self.day_from_moment(s + Clock.days_from_hours(6))
if (3 < k < 27):
temp = k
else:
mid = self.from_fixed(s - 15)
if ((mid.month != self.month) or (mid.leap_month and not self.leap_month)):
temp = mod(k + 15, 30) - 15
else:
temp = mod(k - 15, 30) + 15
est = s + self.day - temp
tau = est - mod(self.day_from_moment(est + Clock.days_from_hours(6)) - self.day + 15, 30) + 15
date = next_int(tau - 1,
lambda d: (self.day_from_moment(self.alt_sunrise(d)) in
[self.day, amod(self.day + 1, 30)]))
return (date + 1) if self.leap_day else date
def korean_location(tee):
"""Return the location for Korean calendar; varies with moment, tee."""
# Seoul city hall at a varying time zone.
if (tee < GregorianDate(1908, MonthOfYear.April, 1).to_fixed()):
#local mean time for longitude 126 deg 58 min
z = 3809/450
elif (tee < GregorianDate(1912, MonthOfYear.January, 1).to_fixed()):
z = 8.5
elif (tee < GregorianDate(1954, MonthOfYear.March, 21).to_fixed()):
z = 9
elif (tee < GregorianDate(1961, MonthOfYear.August, 10).to_fixed()):
z = 8.5
else:
z = 9
return Location(angle(37, 34, 0), angle(126, 58, 0), 0, Clock.days_from_hours(z))
def equation_of_time(cls, tee):
"""Return the equation of time (as fraction of day) for moment, tee.
Adapted from "Astronomical Algorithms" by Jean Meeus,
Willmann_Bell, Inc., 1991."""
c = cls.julian_centuries(tee)
lamb = poly(c, [mpf(280.46645), mpf(36000.76983), mpf(0.0003032)])
anomaly = poly(c, [mpf(357.52910), mpf(35999.05030), mpf(-0.0001559), mpf(-0.00000048)])
eccentricity = poly(c, [mpf(0.016708617), mpf(-0.000042037), mpf(-0.0000001236)])
varepsilon = cls.obliquity(tee)
y = pow(tan_degrees(varepsilon / 2), 2)
equation = ((1/2 / pi) *
(y * sin_degrees(2 * lamb) +
-2 * eccentricity * sin_degrees(anomaly) +
(4 * eccentricity * y * sin_degrees(anomaly) *
cos_degrees(2 * lamb)) +
-0.5 * y * y * sin_degrees(4 * lamb) +
-1.25 * eccentricity * eccentricity * sin_degrees(2 * anomaly)))
return signum(equation) * min(abs(equation), Clock.days_from_hours(mpf(12)))
def standard_from_sundial(self, tee):
"""Return standard time of temporal moment, tee, at location, location."""
date = Clock.fixed_from_moment(tee)
hour = 24 * mod(tee, 1)
if 6 <= hour <= 18:
h = self.daytime_temporal_hour(date)
elif (hour < 6):
h = self.nighttime_temporal_hour(date - 1)
else:
h = self.nighttime_temporal_hour(date)
# return
if 6 <= hour <= 18:
return self.sunrise(date) + ((hour - 6) * h)
elif hour < 6:
return self.sunset(date - 1) + ((hour + 6) * h)
else:
return self.sunset(date) + ((hour - 18) * h)
def ephemeris_correction(cls, tee):
"""Return Dynamical Time minus Universal Time (in days) for
moment, tee. Adapted from "Astronomical Algorithms"
by Jean Meeus, Willmann_Bell, Inc., 1991."""
year = GregorianDate.to_year(ifloor(tee))
c = GregorianDate.date_difference(GregorianDate(1900, JulianMonth.January, 1), GregorianDate(year, JulianMonth.July, 1)) / mpf(36525)
if 1988 <= year <= 2019:
return 1/86400 * (year - 1933)
elif 1900 <= year <= 1987:
return poly(c, [mpf(-0.00002), mpf(0.000297), mpf(0.025184), mpf(-0.181133), mpf(0.553040), mpf(-0.861938), mpf(0.677066), mpf(-0.212591)])
elif 1800 <= year <= 1899:
return poly(c, [mpf(-0.000009), mpf(0.003844), mpf(0.083563), mpf(0.865736), mpf(4.867575), mpf(15.845535), mpf(31.332267), mpf(38.291999), mpf(28.316289), mpf(11.636204), mpf(2.043794)])
elif 1700 <= year <= 1799:
return 1/86400 * poly(year - 1700, [8.118780842, -0.005092142, 0.003336121, -0.0000266484])
elif 1620 <= year <= 1699:
return 1/86400 * poly(year - 1600, [mpf(196.58333), mpf(-4.0675), mpf(0.0219167)])
else:
x = Clock.days_from_hours(mpf(12)) + GregorianDate.date_difference(GregorianDate(1810, JulianMonth.January, 1), GregorianDate(year, JulianMonth.January, 1))
return 1/86400 * (((x * x) / mpf(41048480)) - 15)
elif month == HebrewMonth.KISLEV and day < 30:
extra = [DayOfWeek.Monday, DayOfWeek.Wednesday, DayOfWeek.Friday]
elif month == HebrewMonth.KISLEV and day == 30:
extra = [DayOfWeek.Monday]
elif month in [HebrewMonth.TEVET, HebrewMonth.SHEVAT]:
extra = [DayOfWeek.Sunday, DayOfWeek.Monday]
elif month == HebrewMonth.ADAR and day < 30:
extra = [DayOfWeek.Sunday, DayOfWeek.Monday]
else:
extra = [DayOfWeek.Sunday]
basic.extend(extra)
return map(lambda x: DayOfWeek.from_fixed(x + n), basic)
JAFFA = Location(angle(32, 1, 60), angle(34, 45, 0), 0, Clock.days_from_hours(2))
class HebrewObservationalDate(YearMonthDay):
def __init__(self, year, month, day):
YearMonthDay.__init__(self, year, month, day)
def to_fixed(self):
"""Return fixed date equivalent to Observational Hebrew date."""
year1 = self.year - 1 if self.month >= HebrewMonth.TISHRI else self.year
start = HebrewDate(year1, HebrewMonth.NISAN, 1).to_fixed()
g_year = GregorianDate.to_year(start + 60)
new_year = self.new_year(g_year)
midmonth = new_year + iround(29.5 * (self.month - 1)) + 15
return JAFFA.phasis_on_or_before(midmonth) + self.day - 1
def to_fixed(self):
"""Return fixed date corresponding to Old Hindu solar date s_date."""
return iceiling(self.EPOCH + self.year * self.ARYA_SOLAR_YEAR + (self.month - 1) * self.ARYA_SOLAR_MONTH + self.day + Clock.days_from_hours(-30))
def midday(self, date):
"""Return standard time on fixed date, date, of midday
at location, location."""
return self.standard_from_local(self.local_from_apparent(date + Clock.days_from_hours(mpf(12))))
def to_fixed(self):
"""Return fixed date corresponding to Old Hindu lunar date l_date."""
mina = ((12 * self.year) - 1) * self.ARYA_SOLAR_MONTH
lunar_new_year = self.ARYA_LUNAR_MONTH * (quotient(mina, self.ARYA_LUNAR_MONTH) + 1)
if not self.leap and iceiling((lunar_new_year - mina) / (self.ARYA_SOLAR_MONTH - self.ARYA_LUNAR_MONTH)) <= self.month:
temp = self.month
else:
temp = self.month - 1
temp = self.EPOCH + lunar_new_year + (self.ARYA_LUNAR_MONTH * temp) + ((self.day - 1) * self.ARYA_LUNAR_DAY) + Clock.days_from_hours(-6)
return iceiling(temp)
def dusk(self, date, alpha):
"""Return standard time in evening on fixed date 'date' at
location 'location' when depression angle of sun is alpha."""
result = self.moment_of_depression(date + Clock.days_from_hours(18), alpha, self.EVENING)
return self.standard_from_local(result)
def dawn(self, date, alpha):
"""Return standard time in morning on fixed date date at
location location when depression angle of sun is alpha."""
result = self.moment_of_depression(date + Clock.days_from_hours(6), alpha, self.MORNING)
return self.standard_from_local(result)
def shiva(gregorian_year):
"""Return the list of fixed date(s) of Night of Shiva in Gregorian year, 'gregorian_year'."""
return hindu_lunar_event(11, 29, Clock.days_from_hours(24), gregorian_year)
ignoring parallax and refraction. Adapted from 'Astronomical
Algorithms' by Jean Meeus, Willmann_Bell, Inc., 1998."""
lamb = Lunar.lunar_longitude(tee)
beta = Lunar.lunar_latitude(tee)
alpha = Astro.right_ascension(tee, beta, lamb)
delta = Astro.declination(tee, beta, lamb)
theta0 = Astro.sidereal_from_moment(tee)
cap_H = mod(theta0 + self.longitude - alpha, 360)
altitude = arcsin_degrees(
(sin_degrees(self.latitude) * sin_degrees(delta)) +
(cos_degrees(self.latitude) * cos_degrees(delta) * cos_degrees(cap_H)))
return mod(altitude + 180, 360) - 180
def visible_crescent(self, date):
"""Return S. K. Shaukat's criterion for likely
visibility of crescent moon on eve of date 'date',
at location 'location'."""
tee = self.universal_from_standard(self.dusk(date - 1, mpf(4.5)))
phase = Lunar.lunar_phase(tee)
altitude = self.lunar_altitude(tee)
arc_of_light = arccos_degrees(cos_degrees(Lunar.lunar_latitude(tee)) * cos_degrees(phase))
return ((Lunar.NEW < phase < Lunar.FIRST_QUARTER) and
(mpf(10.6) <= arc_of_light <= 90) and
(altitude > mpf(4.1)))
MECCA = Location(angle(21, 25, 24), angle(39, 49, 24), 298, Clock.days_from_hours(3))
JERUSALEM = Location(31.8, 35.2, 800, Clock.days_from_hours(2))
BRUXELLES = Location(angle(4, 21, 17), angle(50, 50, 47), 800, Clock.days_from_hours(1))
URBANA = Location(40.1, -88.2, 225, Clock.days_from_hours(-6))
GREENWHICH = Location(51.4777815, 0, 46.9, Clock.days_from_hours(0))
def rama(gregorian_year):
"""Return the list of fixed date(s) of Rama's Birthday in Gregorian
year, 'gregorian_year'."""
return hindu_lunar_event(1, 9, Clock.days_from_hours(12), gregorian_year)
