feat: add support for Earth perihelion and aphelion (#30)

BREAKING CHANGE: EventType constants `MOON_APOGEE` and `MOON_PERIGEE` have been renamed to `APOGEE` and `PERIGEE`
2 jaren geleden · 22a5ee0b03
--- a/kosmorrolib/enum.py
+++ b/kosmorrolib/enum.py
@@ -46,8 +46,8 @@ class EventType(Enum):
    CONJUNCTION = 2
    OCCULTATION = 3
    MAXIMAL_ELONGATION = 4
    MOON_PERIGEE = 5
    MOON_APOGEE = 6
    PERIGEE = 5
    APOGEE = 6
    SEASON_CHANGE = 7
    LUNAR_ECLIPSE = 8

--- a/kosmorrolib/events.py
+++ b/kosmorrolib/events.py
@@ -25,7 +25,7 @@ from skyfield.units import Angle
 from skyfield import almanac, eclipselib
 from numpy import pi

 from kosmorrolib.model import Event, Star, Planet, ASTERS, EARTH
 from kosmorrolib.model import Object, Event, Star, Planet, ASTERS, EARTH
 from kosmorrolib.dateutil import translate_to_timezone
 from kosmorrolib.enum import EventType, ObjectIdentifier, SeasonType, LunarEclipseType
 from kosmorrolib.exceptions import OutOfRangeDateError
@@ -225,59 +225,94 @@ def _search_maximal_elongations(
    return events


 def _get_moon_distance():
    earth = get_skf_objects()["earth"]
    moon = get_skf_objects()["moon"]

 def _get_distance(to_aster: Object, from_aster: Object):
    def get_distance(time: Time):
        earth_pos = earth.at(time)
        moon_pos = earth_pos.observe(moon).apparent()
        from_pos = from_aster.get_skyfield_object().at(time)
        to_pos = from_pos.observe(to_aster.get_skyfield_object())

        return moon_pos.distance().au
        return to_pos.distance().km

    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 = []
 def _search_apogee(to_aster: Object, from_aster: Object = EARTH) -> callable:
    """Search for moon apogee

    times, _ = find_maxima(
        start_time, end_time, f=_get_moon_distance(), epsilon=1.0 / 24 / 60
    )
    **Warning:** this is an internal function, not intended for use by end-developers.

    for time in times:
        events.append(
            Event(
                EventType.MOON_APOGEE,
                [moon],
                translate_to_timezone(time.utc_datetime(), timezone),
            )
    Get the moon apogee:
    >>> _search_apogee(ASTERS[1])(get_timescale().utc(2021, 6, 8), get_timescale().utc(2021, 6, 9), 0)
    [<Event type=APOGEE objects=[<Object type=SATELLITE name=MOON />] start=2021-06-08 02:39:40.165271+00:00 end=None details={'distance_km': 406211.04850197025} />]

    Get the Earth's apogee:
    >>> _search_apogee(EARTH, from_aster=ASTERS[0])(get_timescale().utc(2021, 7, 5), get_timescale().utc(2021, 7, 6), 0)
    [<Event type=APOGEE objects=[<Object type=PLANET name=EARTH />] start=2021-07-05 22:35:42.148792+00:00 end=None details={'distance_km': 152100521.91712126} />]
    """

    def f(start_time: Time, end_time: Time, timezone: int) -> [Event]:
        events = []

        times, distances = find_maxima(
            start_time,
            end_time,
            f=_get_distance(to_aster, from_aster),
            epsilon=1.0 / 24 / 60,
        )

    return events
        for i, time in enumerate(times):
            events.append(
                Event(
                    EventType.APOGEE,
                    [to_aster],
                    translate_to_timezone(time.utc_datetime(), timezone),
                    details={"distance_km": distances[i]},
                )
            )

        return events

 def _search_moon_perigee(start_time: Time, end_time: Time, timezone: int) -> [Event]:
    moon = ASTERS[1]
    events = []
    return f

    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),
            )
 def _search_perigee(aster: Object, from_aster: Object = EARTH) -> callable:
    """Search for moon perigee

    **Warning:** this is an internal function, not intended for use by end-developers.

    Get the moon perigee:
    >>> _search_perigee(ASTERS[1])(get_timescale().utc(2021, 5, 26), get_timescale().utc(2021, 5, 27), 0)
    [<Event type=PERIGEE objects=[<Object type=SATELLITE name=MOON />] start=2021-05-26 01:56:01.983455+00:00 end=None details={'distance_km': 357313.9680798693} />]

    Get the Earth's perigee:
    >>> _search_perigee(EARTH, from_aster=ASTERS[0])(get_timescale().utc(2021, 1, 2), get_timescale().utc(2021, 1, 3), 0)
    [<Event type=PERIGEE objects=[<Object type=PLANET name=EARTH />] start=2021-01-02 13:59:00.495905+00:00 end=None details={'distance_km': 147093166.1686309} />]
    """

    def f(start_time: Time, end_time: Time, timezone: int) -> [Event]:
        events = []

        times, distances = find_minima(
            start_time,
            end_time,
            f=_get_distance(aster, from_aster),
            epsilon=1.0 / 24 / 60,
        )

    return events
        for i, time in enumerate(times):
            events.append(
                Event(
                    EventType.PERIGEE,
                    [aster],
                    translate_to_timezone(time.utc_datetime(), timezone),
                    details={"distance_km": distances[i]},
                )
            )

        return events

    return f


 def _search_earth_season_change(
@@ -437,8 +472,10 @@ def get_events(for_date: date = date.today(), timezone: int = 0) -> [Event]:
            _search_oppositions,
            _search_conjunction,
            _search_maximal_elongations,
            _search_moon_apogee,
            _search_moon_perigee,
            _search_apogee(ASTERS[1]),
            _search_perigee(ASTERS[1]),
            _search_apogee(EARTH, from_aster=ASTERS[0]),
            _search_perigee(EARTH, from_aster=ASTERS[0]),
            _search_earth_season_change,
            _search_lunar_eclipse,
        ]:
--- a/tests/init.py
+++ b/tests/init.py
@@ -19,6 +19,5 @@
 from .core import *
 from .data import *
 from .ephemerides import *
 from .events import *
 from .testutils import *
 from .dateutil import *
--- a/tests/events.py
+++ b/tests/events.py
@@ -1,172 +0,0 @@
 #!/usr/bin/env python3

 #    Kosmorrolib - The Library To Compute Your Ephemerides
 #    Copyright (C) 2021  Jérôme Deuchnord <jerome@deuchnord.fr>
 #
 #    This program is free software: you can redistribute it and/or modify
 #    it under the terms of the GNU Affero General Public License as
 #    published by the Free Software Foundation, either version 3 of the
 #    License, or (at your option) any later version.
 #
 #    This program is distributed in the hope that it will be useful,
 #    but WITHOUT ANY WARRANTY; without even the implied warranty of
 #    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 #    GNU Affero General Public License for more details.
 #
 #    You should have received a copy of the GNU Affero General Public License
 #    along with this program.  If not, see <https://www.gnu.org/licenses/>.

 import unittest

 from datetime import date, datetime
 from parameterized import parameterized

 from kosmorrolib import events
 from kosmorrolib.model import Event, ASTERS
 from kosmorrolib.enum import EventType
 from kosmorrolib.exceptions import OutOfRangeDateError

 EXPECTED_EVENTS = [
    (date(2020, 2, 7), []),
    (
        date(2020, 10, 13),
        [Event(EventType.OPPOSITION, [ASTERS[4]], datetime(2020, 10, 13, 23, 25))],
    ),
    (
        date(2022, 12, 8),
        [
            Event(
                EventType.CONJUNCTION,
                [ASTERS[1], ASTERS[4]],
                datetime(2022, 12, 8, 4, 18),
            ),
            Event(EventType.OPPOSITION, [ASTERS[4]], datetime(2022, 12, 8, 5, 41)),
        ],
    ),
    (
        date(2025, 1, 16),
        [Event(EventType.OPPOSITION, [ASTERS[4]], datetime(2025, 1, 16, 2, 38))],
    ),
    (
        date(2027, 2, 19),
        [
            Event(EventType.MOON_PERIGEE, [ASTERS[1]], datetime(2027, 2, 19, 7, 38)),
            Event(EventType.OPPOSITION, [ASTERS[4]], datetime(2027, 2, 19, 15, 50)),
        ],
    ),
    (
        date(2020, 1, 2),
        [
            Event(EventType.MOON_APOGEE, [ASTERS[1]], datetime(2020, 1, 2, 1, 32)),
            Event(
                EventType.CONJUNCTION,
                [ASTERS[2], ASTERS[5]],
                datetime(2020, 1, 2, 16, 41),
            ),
        ],
    ),
    (
        date(2020, 1, 12),
        [
            Event(
                EventType.CONJUNCTION,
                [ASTERS[2], ASTERS[6]],
                datetime(2020, 1, 12, 9, 51),
            ),
            Event(
                EventType.CONJUNCTION,
                [ASTERS[2], ASTERS[9]],
                datetime(2020, 1, 12, 10, 13),
            ),
            Event(
                EventType.CONJUNCTION,
                [ASTERS[6], ASTERS[9]],
                datetime(2020, 1, 12, 16, 57),
            ),
        ],
    ),
    (
        date(2020, 2, 10),
        [
            Event(
                EventType.MAXIMAL_ELONGATION,
                [ASTERS[2]],
                datetime(2020, 2, 10, 13, 46),
                details={"deg": 18.2},
            ),
            Event(EventType.MOON_PERIGEE, [ASTERS[1]], datetime(2020, 2, 10, 20, 34)),
        ],
    ),
    (
        date(2020, 3, 24),
        [
            Event(
                EventType.MAXIMAL_ELONGATION,
                [ASTERS[2]],
                datetime(2020, 3, 24, 1, 56),
                details={"deg": 27.8},
            ),
            Event(EventType.MOON_APOGEE, [ASTERS[1]], datetime(2020, 3, 24, 15, 39)),
            Event(
                EventType.MAXIMAL_ELONGATION,
                [ASTERS[3]],
                datetime(2020, 3, 24, 21, 58),
                details={"deg": 46.1},
            ),
        ],
    ),
    (
        date(2005, 6, 16),
        [
            Event(
                EventType.OCCULTATION,
                [ASTERS[1], ASTERS[5]],
                datetime(2005, 6, 16, 6, 31),
            )
        ],
    ),
    (
        date(2020, 4, 7),
        [Event(EventType.MOON_PERIGEE, [ASTERS[1]], datetime(2020, 4, 7, 18, 14))],
    ),
    (
        date(2020, 1, 29),
        [Event(EventType.MOON_APOGEE, [ASTERS[1]], datetime(2020, 1, 29, 21, 32))],
    ),
 ]


 class EventTestCase(unittest.TestCase):
    def setUp(self) -> None:
        self.maxDiff = None

    @parameterized.expand(EXPECTED_EVENTS)
    def test_search_events(self, d: date, expected_events: [Event]):
        actual_events = events.get_events(d)
        self.assertEqual(
            len(expected_events),
            len(actual_events),
            "Expected %d elements, got %d for date %s.\n%s"
            % (len(expected_events), len(actual_events), d.isoformat(), actual_events),
        )

        for i, expected_event in enumerate(expected_events):
            actual_event = actual_events[i]
            # Remove unnecessary precision (seconds and microseconds)
            actual_event.start_time = datetime(
                actual_event.start_time.year,
                actual_event.start_time.month,
                actual_event.start_time.day,
                actual_event.start_time.hour,
                actual_event.start_time.minute,
            )

            self.assertEqual(expected_event.__dict__, actual_event.__dict__)

    def test_get_events_raises_exception_on_out_of_date_range(self):
        with self.assertRaises(OutOfRangeDateError):
            events.get_events(date(1789, 5, 5))


 if __name__ == "__main__":
    unittest.main()