|
- #!/usr/bin/env python3
-
- from abc import ABC, abstractmethod
- from typing import Union
- from datetime import datetime
-
- from numpy import pi, arcsin
-
- from skyfield.api import Topos, Time
- from skyfield.vectorlib import VectorSum as SkfPlanet
-
- from .core import get_skf_objects
- from .enum import MoonPhaseType, EventType
-
-
- class Serializable(ABC):
- @abstractmethod
- def serialize(self) -> dict:
- pass
-
-
- class MoonPhase(Serializable):
- def __init__(
- self,
- phase_type: MoonPhaseType,
- time: datetime = None,
- next_phase_date: datetime = None,
- ):
- self.phase_type = phase_type
- self.time = time
- self.next_phase_date = next_phase_date
-
- def get_next_phase(self):
- if self.phase_type in [MoonPhaseType.NEW_MOON, MoonPhaseType.WAXING_CRESCENT]:
- return MoonPhaseType.FIRST_QUARTER
- if self.phase_type in [
- MoonPhaseType.FIRST_QUARTER,
- MoonPhaseType.WAXING_GIBBOUS,
- ]:
- return MoonPhaseType.FULL_MOON
- if self.phase_type in [MoonPhaseType.FULL_MOON, MoonPhaseType.WANING_GIBBOUS]:
- return MoonPhaseType.LAST_QUARTER
-
- return MoonPhaseType.NEW_MOON
-
- def serialize(self) -> dict:
- return {
- "phase": self.phase_type.name,
- "time": self.time.isoformat() if self.time is not None else None,
- "next": {
- "phase": self.get_next_phase().name,
- "time": self.next_phase_date.isoformat(),
- },
- }
-
-
- class Object(Serializable):
- """
- An astronomical object.
- """
-
- def __init__(self, name: str, skyfield_name: str, radius: float = None):
- """
- Initialize an astronomical object
-
- :param str name: the official name of the object (may be internationalized)
- :param str skyfield_name: the internal name of the object in Skyfield library
- :param float radius: the radius (in km) of the object
- :param AsterEphemerides ephemerides: the ephemerides associated to the object
- """
- self.name = name
- self.skyfield_name = skyfield_name
- self.radius = radius
-
- def __repr__(self):
- return "<Object type=%s name=%s />" % (self.get_type(), self.name)
-
- def get_skyfield_object(self) -> SkfPlanet:
- return get_skf_objects()[self.skyfield_name]
-
- @abstractmethod
- def get_type(self) -> str:
- pass
-
- def get_apparent_radius(self, time: Time, from_place) -> float:
- """
- Calculate the apparent radius, in degrees, of the object from the given place at a given time.
- :param time:
- :param from_place:
- :return:
- """
- if self.radius is None:
- raise ValueError("Missing radius for %s object" % self.name)
-
- return (
- 360
- / pi
- * arcsin(
- self.radius
- / from_place.at(time).observe(self.get_skyfield_object()).distance().km
- )
- )
-
- def serialize(self) -> dict:
- return {
- "name": self.name,
- "type": self.get_type(),
- "radius": self.radius,
- }
-
-
- class Star(Object):
- def get_type(self) -> str:
- return "star"
-
-
- class Planet(Object):
- def get_type(self) -> str:
- return "planet"
-
-
- class DwarfPlanet(Planet):
- def get_type(self) -> str:
- return "dwarf_planet"
-
-
- class Satellite(Object):
- def get_type(self) -> str:
- return "satellite"
-
-
- class Event(Serializable):
- def __init__(
- self,
- event_type: EventType,
- objects: [Object],
- start_time: datetime,
- end_time: Union[datetime, None] = None,
- details: str = None,
- ):
- self.event_type = event_type
- self.objects = objects
- self.start_time = start_time
- self.end_time = end_time
- self.details = details
-
- def __repr__(self):
- return "<Event type=%s objects=%s start=%s end=%s details=%s />" % (
- self.event_type.name,
- self.objects,
- self.start_time,
- self.end_time,
- self.details,
- )
-
- def get_description(self, show_details: bool = True) -> str:
- description = self.event_type.value % self._get_objects_name()
- if show_details and self.details is not None:
- description += " ({:s})".format(self.details)
- return description
-
- def _get_objects_name(self):
- if len(self.objects) == 1:
- return self.objects[0].name
-
- return tuple(object.name for object in self.objects)
-
- def serialize(self) -> dict:
- return {
- "objects": [object.serialize() for object in self.objects],
- "EventType": self.event_type.name,
- "starts_at": self.start_time.isoformat(),
- "ends_at": self.end_time.isoformat() if self.end_time is not None else None,
- "details": self.details,
- }
-
-
- class AsterEphemerides(Serializable):
- def __init__(
- self,
- rise_time: Union[datetime, None],
- culmination_time: Union[datetime, None],
- set_time: Union[datetime, None],
- aster: Object,
- ):
- self.rise_time = rise_time
- self.culmination_time = culmination_time
- self.set_time = set_time
- self.object = aster
-
- def serialize(self) -> dict:
- return {
- "object": self.object.serialize(),
- "rise_time": self.rise_time.isoformat()
- if self.rise_time is not None
- else None,
- "culmination_time": self.culmination_time.isoformat()
- if self.culmination_time is not None
- else None,
- "set_time": self.set_time.isoformat()
- if self.set_time is not None
- else None,
- }
-
-
- EARTH = Planet("Earth", "EARTH")
-
- ASTERS = [
- Star("Sun", "SUN", radius=696342),
- Satellite("Moon", "MOON", radius=1737.4),
- Planet("Mercury", "MERCURY", radius=2439.7),
- Planet("Venus", "VENUS", radius=6051.8),
- Planet("Mars", "MARS", radius=3396.2),
- Planet("Jupiter", "JUPITER BARYCENTER", radius=71492),
- Planet("Saturn", "SATURN BARYCENTER", radius=60268),
- Planet("Uranus", "URANUS BARYCENTER", radius=25559),
- Planet("Neptune", "NEPTUNE BARYCENTER", radius=24764),
- Planet("Pluto", "PLUTO BARYCENTER", radius=1185),
- ]
-
-
- class Position:
- def __init__(self, latitude: float, longitude: float, aster: Object):
- self.latitude = latitude
- self.longitude = longitude
- self.aster = aster
- self._topos = None
-
- def get_planet_topos(self) -> Topos:
- if self.aster is None:
- raise TypeError("Observation planet must be set.")
-
- if self._topos is None:
- self._topos = self.aster.get_skyfield_object() + Topos(
- latitude_degrees=self.latitude, longitude_degrees=self.longitude
- )
-
- return self._topos
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