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New time period calculation system, bind it also to the UI

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Tobias Zoghaib
2023-12-22 23:20:39 +01:00
parent d21557b0f1
commit f843e01847
5 changed files with 284 additions and 47 deletions
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cinnamon-dynamic-wallpaper@TobiZog/5.4/preferences/scripts/suntimes.py Normal file
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# # import datetime, math
# # day_ms = 1000 * 60 * 60 * 24
# # year_1970 = 2440588
# # year_2000 = 2451545
# # def from_julian(j) -> datetime.date:
# # return datetime.date(ms_date = (j + 0.5 - year_1970))
# # def sun_events_of_day(latitude, longitude, date):
# # rad = math.pi / 180
# # lw = rad * (-longitude)
# # d = (date / day_ms) - 0.5 + year_1970 - year_2000
# # n = math.floor(d - 0.0009 - lw / (2 * math.pi))
# # ds = 0.0009 + lw / (2 * math.pi) + n
# # M = rad * (357.5291 + 0.98560028 * ds)
# # C = rad * (1.9148 * math.sin(M) + 0.02 * math.sin(2 * M) + 0.0003 * math.sin(3 * M))
# # P = rad * 102.9372
# # L = M + C + P + math.pi
# # dec = math.asin(math.sin(rad * 23.4397) * math.sin(L))
# # angles = [-0.833, -6]
# # for angle in angles:
# # angle *= rad
# # angle = math.acos((math.sin(angle) - math.sin(rad * latitude) * math.sin(dec)) / (math.cos(rad * latitude) * math.cos(dec)))
# # angle = 0.0009 + (angle + lw) / (2 * math.pi) + n
# # j_noon = year_2000 + ds + 0.0053 * math.sin(M) - 0.0069 * math.sin(2 * L)
# # print(from_julian(j_noon - (year_2000 + angles[1] + 0.0053 * math.sin(M) - 0.0069 * math.sin(2 * L) - j_noon)))
# # sun_events_of_day(48.1663, 11.5683, datetime.datetime.now())
# import datetime, math
# from math import cos, sin, acos, asin, tan
# from math import degrees as deg, radians as rad
# from datetime import date, datetime, time
# DAY_MS = 1000 * 60 * 60 * 24
# YEAR_1970 = 2440588
# YEAR_2000 = 2451545
# def date_to_julian(year, month, day):
# if month <= 2:
# year += 1
# month += 12
# A = math.trunc(year / 100.)
# B = 2 - A + math.trunc(A / 4.)
# if year < 0:
# C = math.trunc((365.25 * year) - 0.75)
# else:
# C = math.trunc(365.25 * year)
# D = math.trunc(30.6001 * (month + 1))
# return B + C + D + day + 1720994.5
# latitude_rad = rad(latitude)
# n = date_to_julian(datetime.now().year, datetime.now().month, datetime.now().day) - YEAR_2000 + 0.0008
# jstar = n - deg(longitude) / 360
# M_deg = (357.5291 + 0.98560028 * jstar) % 360
# M = M_deg * math.pi / 180
# C = 1.9148 * sin(M) + 0.0200 * sin(2*M) + 0.003 * sin(3*M)
# lamda = math.fmod(M_deg + C + 180 + 102.9372, 360) * math.pi / 180
# Jtransit = 2451545.5 + jstar + 0.0053 * sin(M) - 0.0069 * sin(2 * lamda)
# earth_tilt_rad = rad(23.44)
# angle_delta = asin(sin(lamda) * sin(earth_tilt_rad))
# sun_disc_rad = rad(-0.83)
# os_omega =
# print(date_to_julian(2023, 12, 12))
# #s = sun(lat=48.1663, long=11.5683)
from math import pi, sin, asin, acos, cos
from datetime import datetime, timedelta
DAY_MS = 1000 * 60 * 60 * 24
YEAR_1970 = 2440588
YEAR_2000 = 2451545
class Suntimes:
def __init__(self, latitude, longitude) -> None:
self.latitude = latitude
self.longitude = longitude
self.date = (datetime.utcnow() - datetime(1970, 1, 1)).total_seconds() * 1000
self.sun_events_of_day()
def from_julian(self, j_date) -> datetime:
j_date = (j_date + 0.5 - YEAR_1970) * DAY_MS
return datetime.fromtimestamp(j_date / 1000)
def sun_events_of_day(self):
rad = pi / 180
lw = rad * (-self.longitude)
d = (self.date / DAY_MS) - 0.5 + YEAR_1970 - YEAR_2000
n = round(d - 0.0009 - lw / (2 * pi))
ds = 0.0009 + lw / (2 * pi) + n
self.M = rad * (357.5291 + 0.98560028 * ds)
C = rad * (1.9148 * sin(self.M) + 0.02 * sin(2 * self.M) + 0.0003 * sin(3 * self.M))
P = rad * 102.9372
self.L = self.M + C + P + pi
dec = asin(sin(rad * 23.4397) * sin(self.L))
self.j_noon = YEAR_2000 + ds + 0.0053 * sin(self.M) - 0.0069 * sin(2 * self.L)
# -8 = Start of Civil dawn/dusk
# -2 = Start of Sunrise/Sunset
# 0 = Start/End of daylight phases
self.angles = [-10, -4, 0]
for i in range(0, len(self.angles)):
self.angles[i] = rad * self.angles[i]
self.angles[i] = acos((sin(self.angles[i]) - sin(rad * self.latitude) * sin(dec)) /
(cos(rad * self.latitude) * cos(dec)))
self.angles[i] = 0.0009 + (self.angles[i] + lw) / (2 * pi) + n
def angle_correction(self, angle: float) -> datetime:
return (YEAR_2000 + angle + 0.0053 * sin(self.M) - 0.0069 * sin(2 * self.L))
def get_time_period(self, period_nr: int) -> list:
""" Get start and end time of a time period
Args:
period_nr (int): Number between 0 and 9
0 = Early Night
1 = Civial dawn
2 = Sunrise
3 = Morning
4 = Noon
5 = Afternoon
6 = Evening
7 = Sunset
8 = Civial Dusk
9 = Late Night
Returns:
list: Two datetime objects
"""
if period_nr == 0:
res = [datetime.now().replace(hour=0, minute=0, second=0, microsecond=0),
self.from_julian(2 * self.j_noon - self.angle_correction(self.angles[0])) - timedelta(minutes=1)]
elif period_nr <= 2:
res = [self.from_julian(2 * self.j_noon - self.angle_correction(self.angles[period_nr - 1])),
self.from_julian(2 * self.j_noon - self.angle_correction(self.angles[period_nr])) - timedelta(minutes=1)]
elif period_nr <= 6:
daylength = self.get_time_period(8)[0] - self.get_time_period(2)[1]
res = [self.get_time_period(2)[1] + ((daylength / 4) * (period_nr - 3)),
self.get_time_period(2)[1] + ((daylength / 4) * (period_nr - 2))]
elif period_nr <= 8:
res = [self.from_julian(self.angle_correction(self.angles[9 - period_nr])),
self.from_julian(self.angle_correction(self.angles[8 - period_nr])) - timedelta(minutes=1)]
elif period_nr == 9:
res = [self.from_julian(YEAR_2000 + self.angles[0] + 0.0053 * sin(self.M) - 0.0069 * sin(2 * self.L)),
datetime.now().replace(hour=23, minute=59, second=59, microsecond=0)]
return res