#!/usr/bin/env python3
from datetime import date as date_type
from skyfield.errors import EphemerisRangeError
from skyfield.timelib import Time
from skyfield.searchlib import find_discrete, find_maxima, find_minima
from numpy import pi
from .model import Event, Star, Planet, ASTERS
from .dateutil import translate_to_timezone
from .enum import EventType
from .exceptions import OutOfRangeDateError
from .core import get_timescale, get_skf_objects, flatten_list
def _search_conjunction(start_time: Time, end_time: Time, timezone: int) -> [Event]:
earth = get_skf_objects()["earth"]
aster1 = None
aster2 = None
def is_in_conjunction(time: Time):
earth_pos = earth.at(time)
_, aster1_lon, _ = (
earth_pos.observe(aster1.get_skyfield_object()).apparent().ecliptic_latlon()
)
_, aster2_lon, _ = (
earth_pos.observe(aster2.get_skyfield_object()).apparent().ecliptic_latlon()
)
return ((aster1_lon.radians - aster2_lon.radians) / pi % 2.0).astype(
"int8"
) == 0
is_in_conjunction.rough_period = 60.0
computed = []
conjunctions = []
for aster1 in ASTERS:
# Ignore the Sun
if isinstance(aster1, Star):
continue
for aster2 in ASTERS:
if isinstance(aster2, Star) or aster2 == aster1 or aster2 in computed:
continue
times, is_conjs = find_discrete(start_time, end_time, is_in_conjunction)
for i, time in enumerate(times):
if is_conjs[i]:
aster1_pos = (aster1.get_skyfield_object() - earth).at(time)
aster2_pos = (aster2.get_skyfield_object() - earth).at(time)
distance = aster1_pos.separation_from(aster2_pos).degrees
if distance - aster2.get_apparent_radius(
time, earth
) < aster1.get_apparent_radius(time, earth):
occulting_aster = (
[aster1, aster2]
if aster1_pos.distance().km < aster2_pos.distance().km
else [aster2, aster1]
)
conjunctions.append(
Event(
EventType.OCCULTATION,
occulting_aster,
translate_to_timezone(time.utc_datetime(), timezone),
)
)
else:
conjunctions.append(
Event(
EventType.CONJUNCTION,
[aster1, aster2],
translate_to_timezone(time.utc_datetime(), timezone),
)
)
computed.append(aster1)
return conjunctions
def _search_oppositions(start_time: Time, end_time: Time, timezone: int) -> [Event]:
earth = get_skf_objects()["earth"]
sun = get_skf_objects()["sun"]
aster = None
def is_oppositing(time: Time) -> [bool]:
earth_pos = earth.at(time)
sun_pos = earth_pos.observe(
sun
).apparent() # Never do this without eyes protection!
aster_pos = earth_pos.observe(get_skf_objects()[aster.skyfield_name]).apparent()
_, lon1, _ = sun_pos.ecliptic_latlon()
_, lon2, _ = aster_pos.ecliptic_latlon()
return (lon1.degrees - lon2.degrees) > 180
is_oppositing.rough_period = 1.0
events = []
for aster in ASTERS:
if not isinstance(aster, Planet) or aster.skyfield_name in ["MERCURY", "VENUS"]:
continue
times, _ = find_discrete(start_time, end_time, is_oppositing)
for time in times:
events.append(
Event(
EventType.OPPOSITION,
[aster],
translate_to_timezone(time.utc_datetime(), timezone),
)
)
return events
def _search_maximal_elongations(
start_time: Time, end_time: Time, timezone: int
) -> [Event]:
earth = get_skf_objects()["earth"]
sun = get_skf_objects()["sun"]
aster = None
def get_elongation(time: Time):
sun_pos = (sun - earth).at(time)
aster_pos = (aster.get_skyfield_object() - earth).at(time)
separation = sun_pos.separation_from(aster_pos)
return separation.degrees
get_elongation.rough_period = 1.0
events = []
for aster in ASTERS:
if aster.skyfield_name not in ["MERCURY", "VENUS"]:
continue
times, elongations = find_maxima(
start_time, end_time, f=get_elongation, epsilon=1.0 / 24 / 3600, num=12
)
for i, time in enumerate(times):
elongation = elongations[i]
events.append(
Event(
EventType.MAXIMAL_ELONGATION,
[aster],
translate_to_timezone(time.utc_datetime(), timezone),
details="{:.3n}°".format(elongation),
)
)
return events
def _get_moon_distance():
earth = get_skf_objects()["earth"]
moon = get_skf_objects()["moon"]
def get_distance(time: Time):
earth_pos = earth.at(time)
moon_pos = earth_pos.observe(moon).apparent()
return moon_pos.distance().au
get_distance.rough_period = 1.0
return get_distance
def _search_moon_apogee(start_time: Time, end_time: Time, timezone: int) -> [Event]:
moon = ASTERS[1]
events = []
times, _ = find_maxima(
start_time, end_time, f=_get_moon_distance(), epsilon=1.0 / 24 / 60
)
for time in times:
events.append(
Event(
EventType.MOON_APOGEE,
[moon],
translate_to_timezone(time.utc_datetime(), timezone),
)
)
return events
def _search_moon_perigee(start_time: Time, end_time: Time, timezone: int) -> [Event]:
moon = ASTERS[1]
events = []
times, _ = find_minima(
start_time, end_time, f=_get_moon_distance(), epsilon=1.0 / 24 / 60
)
for time in times:
events.append(
Event(
EventType.MOON_PERIGEE,
[moon],
translate_to_timezone(time.utc_datetime(), timezone),
)
)
return events
def get_events(date: date_type = date_type.today(), timezone: int = 0) -> [Event]:
"""Calculate and return a list of events for the given date, adjusted to the given timezone if any.
Find events that happen on April 4th, 2020 (show hours in UTC):
>>> get_events(date_type(2020, 4, 4))
[, ] start=2020-04-04 01:14:39.063308+00:00 end=None details=None />]
Find events that happen on April 4th, 2020 (show timezones in UTC+2):
>>> get_events(date_type(2020, 4, 4), 2)
[, ] start=2020-04-04 03:14:39.063267+02:00 end=None details=None />]
Find events that happen on April 3rd, 2020 (show timezones in UTC-2):
>>> get_events(date_type(2020, 4, 3), -2)
[, ] start=2020-04-03 23:14:39.063388-02:00 end=None details=None />]
:param date: the date for which the events must be calculated
:param timezone: the timezone to adapt the results to. If not given, defaults to 0.
:return: a list of events found for the given date.
"""
start_time = get_timescale().utc(date.year, date.month, date.day, -timezone)
end_time = get_timescale().utc(date.year, date.month, date.day + 1, -timezone)
try:
found_events = []
for fun in [
_search_oppositions,
_search_conjunction,
_search_maximal_elongations,
_search_moon_apogee,
_search_moon_perigee,
]:
found_events.append(fun(start_time, end_time, timezone))
return sorted(flatten_list(found_events), key=lambda event: event.start_time)
except EphemerisRangeError as error:
start_date = translate_to_timezone(error.start_time.utc_datetime(), timezone)
end_date = translate_to_timezone(error.end_time.utc_datetime(), timezone)
start_date = date_type(start_date.year, start_date.month, start_date.day)
end_date = date_type(end_date.year, end_date.month, end_date.day)
raise OutOfRangeDateError(start_date, end_date) from error