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feat: add support for maximal elongations of Mercury and Venus

tags/v0.6.0
Jérôme Deuchnord hace 4 años
padre
commit
9dbc093631
No se encontró ninguna clave conocida en la base de datos para esta firma ID de clave GPG: BC6F3C345B7D33B0
Se han modificado 8 ficheros con 235 adiciones y 133 borrados
  1. +2
    -1
      kosmorrolib/assets/pdf/template.tex
  2. +0
    -54
      kosmorrolib/core.py
  3. +69
    -9
      kosmorrolib/data.py
  4. +11
    -7
      kosmorrolib/ephemerides.py
  5. +34
    -4
      kosmorrolib/events.py
  6. +48
    -43
      kosmorrolib/locales/messages.pot
  7. +44
    -15
      test/dumper.py
  8. +27
    -0
      test/events.py

+ 2
- 1
kosmorrolib/assets/pdf/template.tex Ver fichero

@@ -6,8 +6,9 @@
\usepackage{graphicx}
\usepackage{hyperref}

% Fix non-break spaces issues
% Fix Unicode issues
\DeclareUnicodeCharacter{202F}{~}
\DeclareUnicodeCharacter{00B0}{$^\circ$}

\hypersetup{pdfinfo={
Title={+++DOCUMENT-TITLE+++},


+ 0
- 54
kosmorrolib/core.py Ver fichero

@@ -18,30 +18,13 @@

from shutil import rmtree
from pathlib import Path
from typing import Union

from skyfield.api import Loader
from skyfield.timelib import Time
from skyfield.nutationlib import iau2000b

from .data import Star, Planet, Satellite, MOON_PHASES, MoonPhase
from .i18n import _

CACHE_FOLDER = str(Path.home()) + '/.kosmorro-cache'

MONTHS = ['JAN', 'FEB', 'MAR', 'APR', 'MAY', 'JUN', 'JUL', 'AUG', 'SEP', 'OCT', 'NOV', 'DEC']

ASTERS = [Star(_('Sun'), 'SUN'),
Satellite(_('Moon'), 'MOON'),
Planet(_('Mercury'), 'MERCURY'),
Planet(_('Venus'), 'VENUS'),
Planet(_('Mars'), 'MARS'),
Planet(_('Jupiter'), 'JUPITER BARYCENTER'),
Planet(_('Saturn'), 'SATURN BARYCENTER'),
Planet(_('Uranus'), 'URANUS BARYCENTER'),
Planet(_('Neptune'), 'NEPTUNE BARYCENTER'),
Planet(_('Pluto'), 'PLUTO BARYCENTER')]


def get_loader():
return Loader(CACHE_FOLDER)
@@ -63,43 +46,6 @@ def clear_cache():
rmtree(CACHE_FOLDER)


def skyfield_to_moon_phase(times: [Time], vals: [int], now: Time) -> Union[MoonPhase, None]:
tomorrow = get_timescale().utc(now.utc_datetime().year, now.utc_datetime().month, now.utc_datetime().day + 1)

phases = list(MOON_PHASES.keys())
current_phase = None
current_phase_time = None
next_phase_time = None
i = 0

if len(times) == 0:
return None

for i, time in enumerate(times):
if now.utc_iso() <= time.utc_iso():
if vals[i] in [0, 2, 4, 6]:
if time.utc_datetime() < tomorrow.utc_datetime():
current_phase_time = time
current_phase = phases[vals[i]]
else:
i -= 1
current_phase_time = None
current_phase = phases[vals[i]]
else:
current_phase = phases[vals[i]]

break

for j in range(i + 1, len(times)):
if vals[j] in [0, 2, 4, 6]:
next_phase_time = times[j]
break

return MoonPhase(current_phase,
current_phase_time.utc_datetime() if current_phase_time is not None else None,
next_phase_time.utc_datetime() if next_phase_time is not None else None)


def flatten_list(the_list: list):
new_list = []
for item in the_list:


+ 69
- 9
kosmorrolib/data.py Ver fichero

@@ -20,8 +20,10 @@ from abc import ABC, abstractmethod
from typing import Union
from datetime import datetime

from skyfield.api import Topos
from skyfield.api import Topos, Time
from skyfield.vectorlib import VectorSum as SkfPlanet

from .core import get_skf_objects, get_timescale
from .i18n import _

MOON_PHASES = {
@@ -37,7 +39,8 @@ MOON_PHASES = {

EVENTS = {
'OPPOSITION': {'message': _('%s is in opposition')},
'CONJUNCTION': {'message': _('%s and %s are in conjunction')}
'CONJUNCTION': {'message': _('%s and %s are in conjunction')},
'MAXIMAL_ELONGATION': {'message': _("%s's largest elongation")}
}


@@ -115,6 +118,9 @@ class Object(ABC):
self.skyfield_name = skyfield_name
self.ephemerides = ephemerides

def get_skyfield_object(self) -> SkfPlanet:
return get_skf_objects()[self.skyfield_name]

@abstractmethod
def get_type(self) -> str:
pass
@@ -142,23 +148,77 @@ class Satellite(Object):

class Event:
def __init__(self, event_type: str, objects: [Object], start_time: datetime,
end_time: Union[datetime, None] = None):
end_time: Union[datetime, None] = None, details: str = None):
if event_type not in EVENTS.keys():
raise ValueError('event_type parameter must be one of the following: %s (got %s)' % (
', '.join(EVENTS.keys()),
event_type)
)
accepted_types = ', '.join(EVENTS.keys())
raise ValueError('event_type parameter must be one of the following: %s (got %s)' % (accepted_types,
event_type))

self.event_type = event_type
self.objects = objects
self.start_time = start_time
self.end_time = end_time
self.details = details

def get_description(self) -> str:
return EVENTS[self.event_type]['message'] % self._get_objects_name()
def get_description(self, show_details: bool = True) -> str:
description = EVENTS[self.event_type]['message'] % 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 skyfield_to_moon_phase(times: [Time], vals: [int], now: Time) -> Union[MoonPhase, None]:
tomorrow = get_timescale().utc(now.utc_datetime().year, now.utc_datetime().month, now.utc_datetime().day + 1)

phases = list(MOON_PHASES.keys())
current_phase = None
current_phase_time = None
next_phase_time = None
i = 0

if len(times) == 0:
return None

for i, time in enumerate(times):
if now.utc_iso() <= time.utc_iso():
if vals[i] in [0, 2, 4, 6]:
if time.utc_datetime() < tomorrow.utc_datetime():
current_phase_time = time
current_phase = phases[vals[i]]
else:
i -= 1
current_phase_time = None
current_phase = phases[vals[i]]
else:
current_phase = phases[vals[i]]

break

for j in range(i + 1, len(times)):
if vals[j] in [0, 2, 4, 6]:
next_phase_time = times[j]
break

return MoonPhase(current_phase,
current_phase_time.utc_datetime() if current_phase_time is not None else None,
next_phase_time.utc_datetime() if next_phase_time is not None else None)


MONTHS = ['JAN', 'FEB', 'MAR', 'APR', 'MAY', 'JUN', 'JUL', 'AUG', 'SEP', 'OCT', 'NOV', 'DEC']

ASTERS = [Star(_('Sun'), 'SUN'),
Satellite(_('Moon'), 'MOON'),
Planet(_('Mercury'), 'MERCURY'),
Planet(_('Venus'), 'VENUS'),
Planet(_('Mars'), 'MARS'),
Planet(_('Jupiter'), 'JUPITER BARYCENTER'),
Planet(_('Saturn'), 'SATURN BARYCENTER'),
Planet(_('Uranus'), 'URANUS BARYCENTER'),
Planet(_('Neptune'), 'NEPTUNE BARYCENTER'),
Planet(_('Pluto'), 'PLUTO BARYCENTER')]

+ 11
- 7
kosmorrolib/ephemerides.py Ver fichero

@@ -24,8 +24,8 @@ from skyfield.searchlib import find_discrete, find_maxima
from skyfield.timelib import Time
from skyfield.constants import tau

from .data import Object, Position, AsterEphemerides, MoonPhase
from .core import get_skf_objects, get_timescale, get_iau2000b, ASTERS, MONTHS, skyfield_to_moon_phase
from .data import Object, Position, AsterEphemerides, MoonPhase, ASTERS, MONTHS, skyfield_to_moon_phase
from .core import get_skf_objects, get_timescale, get_iau2000b

RISEN_ANGLE = -0.8333

@@ -88,6 +88,7 @@ class EphemeridesComputer:
rise_times, arr = find_discrete(start_time, end_time, is_risen)
try:
culmination_time, _ = find_maxima(start_time, end_time, f=get_angle, epsilon=1./3600/24, num=12)
culmination_time = culmination_time[0] if len(culmination_time) > 0 else None
except ValueError:
culmination_time = None

@@ -98,12 +99,15 @@ class EphemeridesComputer:
rise_time = rise_times[0] if arr[0] else None
set_time = rise_times[0] if not arr[0] else None

culmination_time = culmination_time[0] if culmination_time is not None else None

# Convert the Time instances to Python datetime objects
rise_time = rise_time.utc_datetime().replace(microsecond=0)
culmination_time = culmination_time.utc_datetime().replace(microsecond=0)
set_time = set_time.utc_datetime().replace(microsecond=0)
if rise_time is not None:
rise_time = rise_time.utc_datetime().replace(microsecond=0)

if culmination_time is not None:
culmination_time = culmination_time.utc_datetime().replace(microsecond=0)

if set_time is not None:
set_time = set_time.utc_datetime().replace(microsecond=0) if set_time is not None else None

aster.ephemerides = AsterEphemerides(rise_time, culmination_time, set_time)
return aster


+ 34
- 4
kosmorrolib/events.py Ver fichero

@@ -19,10 +19,10 @@
from datetime import date as date_type

from skyfield.timelib import Time
from skyfield.almanac import find_discrete
from skyfield.searchlib import find_discrete, find_maxima

from .data import Event, Planet
from .core import get_timescale, get_skf_objects, ASTERS, flatten_list
from .data import Event, Planet, ASTERS
from .core import get_timescale, get_skf_objects, flatten_list


def _search_conjunction(start_time: Time, end_time: Time) -> [Event]:
@@ -91,11 +91,41 @@ def _search_oppositions(start_time: Time, end_time: Time) -> [Event]:
return events


def _search_maximal_elongations(start_time: Time, end_time: Time) -> [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./24/3600, num=12)

for i, time in enumerate(times):
elongation = elongations[i]
events.append(Event('MAXIMAL_ELONGATION', [aster], time.utc_datetime(),
details='{:.3n}°'.format(elongation)))

return events


def search_events(date: date_type) -> [Event]:
start_time = get_timescale().utc(date.year, date.month, date.day)
end_time = get_timescale().utc(date.year, date.month, date.day + 1)

return sorted(flatten_list([
_search_oppositions(start_time, end_time),
_search_conjunction(start_time, end_time)
_search_conjunction(start_time, end_time),
_search_maximal_elongations(start_time, end_time)
]), key=lambda event: event.start_time)

+ 48
- 43
kosmorrolib/locales/messages.pot Ver fichero

@@ -8,7 +8,7 @@ msgid ""
msgstr ""
"Project-Id-Version: kosmorro 0.5.2\n"
"Report-Msgid-Bugs-To: EMAIL@ADDRESS\n"
"POT-Creation-Date: 2020-02-17 20:58+0100\n"
"POT-Creation-Date: 2020-02-21 20:14+0100\n"
"PO-Revision-Date: YEAR-MO-DA HO:MI+ZONE\n"
"Last-Translator: FULL NAME <EMAIL@ADDRESS>\n"
"Language-Team: LANGUAGE <LL@li.org>\n"
@@ -17,86 +17,91 @@ msgstr ""
"Content-Transfer-Encoding: 8bit\n"
"Generated-By: Babel 2.8.0\n"

#: kosmorrolib/core.py:34
msgid "Sun"
#: kosmorrolib/data.py:30
msgid "New Moon"
msgstr ""

#: kosmorrolib/core.py:35
msgid "Moon"
#: kosmorrolib/data.py:31
msgid "Waxing crescent"
msgstr ""

#: kosmorrolib/core.py:36
msgid "Mercury"
#: kosmorrolib/data.py:32
msgid "First Quarter"
msgstr ""

#: kosmorrolib/core.py:37
msgid "Venus"
#: kosmorrolib/data.py:33
msgid "Waxing gibbous"
msgstr ""

#: kosmorrolib/core.py:38
msgid "Mars"
#: kosmorrolib/data.py:34
msgid "Full Moon"
msgstr ""

#: kosmorrolib/core.py:39
msgid "Jupiter"
#: kosmorrolib/data.py:35
msgid "Waning gibbous"
msgstr ""

#: kosmorrolib/core.py:40
msgid "Saturn"
#: kosmorrolib/data.py:36
msgid "Last Quarter"
msgstr ""

#: kosmorrolib/core.py:41
msgid "Uranus"
#: kosmorrolib/data.py:37
msgid "Waning crescent"
msgstr ""

#: kosmorrolib/core.py:42
msgid "Neptune"
#: kosmorrolib/data.py:41
#, python-format
msgid "%s is in opposition"
msgstr ""

#: kosmorrolib/core.py:43
msgid "Pluto"
#: kosmorrolib/data.py:42
#, python-format
msgid "%s and %s are in conjunction"
msgstr ""

#: kosmorrolib/data.py:28
msgid "New Moon"
#: kosmorrolib/data.py:43
#, python-format
msgid "%s's largest elongation"
msgstr ""

#: kosmorrolib/data.py:29
msgid "Waxing crescent"
#: kosmorrolib/data.py:215
msgid "Sun"
msgstr ""

#: kosmorrolib/data.py:30
msgid "First Quarter"
#: kosmorrolib/data.py:216
msgid "Moon"
msgstr ""

#: kosmorrolib/data.py:31
msgid "Waxing gibbous"
#: kosmorrolib/data.py:217
msgid "Mercury"
msgstr ""

#: kosmorrolib/data.py:32
msgid "Full Moon"
#: kosmorrolib/data.py:218
msgid "Venus"
msgstr ""

#: kosmorrolib/data.py:33
msgid "Waning gibbous"
#: kosmorrolib/data.py:219
msgid "Mars"
msgstr ""

#: kosmorrolib/data.py:34
msgid "Last Quarter"
#: kosmorrolib/data.py:220
msgid "Jupiter"
msgstr ""

#: kosmorrolib/data.py:35
msgid "Waning crescent"
#: kosmorrolib/data.py:221
msgid "Saturn"
msgstr ""

#: kosmorrolib/data.py:39
#, python-format
msgid "%s is in opposition"
#: kosmorrolib/data.py:222
msgid "Uranus"
msgstr ""

#: kosmorrolib/data.py:40
#, python-format
msgid "%s and %s are in conjunction"
#: kosmorrolib/data.py:223
msgid "Neptune"
msgstr ""

#: kosmorrolib/data.py:224
msgid "Pluto"
msgstr ""

#: kosmorrolib/dumper.py:35


+ 44
- 15
test/dumper.py Ver fichero

@@ -23,7 +23,17 @@ class DumperTestCase(unittest.TestCase):
' "Mars"\n'
' ],\n'
' "start_time": "2019-10-14T23:00:00",\n'
' "end_time": null\n'
' "end_time": null,\n'
' "details": null\n'
' },\n'
' {\n'
' "event_type": "MAXIMAL_ELONGATION",\n'
' "objects": [\n'
' "Venus"\n'
' ],\n'
' "start_time": "2019-10-14T12:00:00",\n'
' "end_time": null,\n'
' "details": "42.0\\u00b0"\n'
' }\n'
' ],\n'
' "ephemerides": [\n'
@@ -52,7 +62,17 @@ class DumperTestCase(unittest.TestCase):
' "Mars"\n'
' ],\n'
' "start_time": "2019-10-14T23:00:00",\n'
' "end_time": null\n'
' "end_time": null,\n'
' "details": null\n'
' },\n'
' {\n'
' "event_type": "MAXIMAL_ELONGATION",\n'
' "objects": [\n'
' "Venus"\n'
' ],\n'
' "start_time": "2019-10-14T12:00:00",\n'
' "end_time": null,\n'
' "details": "42.0\\u00b0"\n'
' }\n'
' ],\n'
' "ephemerides": [\n'
@@ -92,15 +112,16 @@ class DumperTestCase(unittest.TestCase):

def test_text_dumper_with_events(self):
ephemerides = self._get_data()
self.assertEqual('Monday October 14, 2019\n\n'
'Object Rise time Culmination time Set time\n'
'-------- ----------- ------------------ ----------\n'
'Mars - - -\n\n'
'Moon phase: Full Moon\n'
'Last Quarter on Monday October 21, 2019 at 00:00\n\n'
'Expected events:\n'
'23:00 Mars is in opposition\n\n'
'Note: All the hours are given in UTC.',
self.assertEqual("Monday October 14, 2019\n\n"
"Object Rise time Culmination time Set time\n"
"-------- ----------- ------------------ ----------\n"
"Mars - - -\n\n"
"Moon phase: Full Moon\n"
"Last Quarter on Monday October 21, 2019 at 00:00\n\n"
"Expected events:\n"
"23:00 Mars is in opposition\n"
"12:00 Venus's largest elongation (42.0°)\n\n"
"Note: All the hours are given in UTC.",
TextDumper(ephemerides, self._get_events(), date=date(2019, 10, 14), with_colors=False).to_string())

def test_text_dumper_without_ephemerides_and_with_events(self):
@@ -109,7 +130,8 @@ class DumperTestCase(unittest.TestCase):
'Moon phase: Full Moon\n'
'Last Quarter on Monday October 21, 2019 at 00:00\n\n'
'Expected events:\n'
'23:00 Mars is in opposition\n\n'
'23:00 Mars is in opposition\n'
"12:00 Venus's largest elongation (42.0°)\n\n"
'Note: All the hours are given in UTC.',
TextDumper(ephemerides, self._get_events(), date=date(2019, 10, 14), with_colors=False).to_string())

@@ -122,7 +144,8 @@ class DumperTestCase(unittest.TestCase):
'Moon phase: Full Moon\n'
'Last Quarter on Monday October 21, 2019 at 01:00\n\n'
'Expected events:\n'
'Oct 15, 00:00 Mars is in opposition\n\n'
'Oct 15, 00:00 Mars is in opposition\n'
"13:00 Venus's largest elongation (42.0°)\n\n"
'Note: All the hours are given in the UTC+1 timezone.',
TextDumper(ephemerides, self._get_events(), date=date(2019, 10, 14), with_colors=False, timezone=1).to_string())

@@ -134,7 +157,8 @@ class DumperTestCase(unittest.TestCase):
'Moon phase: Full Moon\n'
'Last Quarter on Sunday October 20, 2019 at 23:00\n\n'
'Expected events:\n'
'22:00 Mars is in opposition\n\n'
'22:00 Mars is in opposition\n'
"11:00 Venus's largest elongation (42.0°)\n\n"
'Note: All the hours are given in the UTC-1 timezone.',
TextDumper(ephemerides, self._get_events(), date=date(2019, 10, 14), with_colors=False, timezone=-1).to_string())

@@ -146,6 +170,7 @@ class DumperTestCase(unittest.TestCase):
self.assertRegex(latex, r'\\section{\\sffamily Ephemerides of the day}')
self.assertRegex(latex, r'\\object\{Mars\}\{-\}\{-\}\{-\}')
self.assertRegex(latex, r'\\event\{23:00\}\{Mars is in opposition\}')
self.assertRegex(latex, r"\\event\{12:00\}\{Venus's largest elongation \(42.0°\)\}")

latex = _LatexDumper(self._get_data(aster_rise_set=True),
self._get_events(), date=date(2019, 10, 14)).to_string()
@@ -157,6 +182,7 @@ class DumperTestCase(unittest.TestCase):
self.assertRegex(latex, 'Full Moon')
self.assertRegex(latex, r'\\section{\\sffamily Expected events}')
self.assertRegex(latex, r'\\event\{23:00\}\{Mars is in opposition\}')
self.assertRegex(latex, r"\\event\{12:00\}\{Venus's largest elongation \(42.0°\)\}")

self.assertNotRegex(latex, r'\\object\{Mars\}\{-\}\{-\}\{-\}')
self.assertNotRegex(latex, r'\\section{\\sffamily Ephemerides of the day}')
@@ -186,7 +212,10 @@ class DumperTestCase(unittest.TestCase):
def _get_events():
return [Event('OPPOSITION',
[Planet('Mars', 'MARS')],
datetime(2019, 10, 14, 23, 00))
datetime(2019, 10, 14, 23, 00)),
Event('MAXIMAL_ELONGATION',
[Planet('Venus', 'VENUS')],
datetime(2019, 10, 14, 12, 00), details='42.0°'),
]




+ 27
- 0
test/events.py Ver fichero

@@ -55,6 +55,33 @@ class MyTestCase(unittest.TestCase):

i += 1

def test_find_maximal_elongation(self):
e = events.search_events(date(2020, 2, 10))
self.assertEquals(1, len(e), 'Expected 1 events, got %d.' % len(e))
e = e[0]
self.assertEquals('MAXIMAL_ELONGATION', e.event_type)
self.assertEquals(1, len(e.objects))
self.assertEquals('MERCURY', e.objects[0].skyfield_name)
self.assertEqual('18.2°', e.details)
self.assertEquals((2020, 2, 10, 13, 46), (e.start_time.year, e.start_time.month, e.start_time.day,
e.start_time.hour, e.start_time.minute))

e = events.search_events(date(2020, 3, 24))
self.assertEquals(2, len(e), 'Expected 2 events, got %d.' % len(e))
self.assertEquals('MAXIMAL_ELONGATION', e[0].event_type)
self.assertEquals(1, len(e[0].objects))
self.assertEquals('MERCURY', e[0].objects[0].skyfield_name)
self.assertEqual('27.8°', e[0].details)
self.assertEquals((2020, 3, 24, 1, 56), (e[0].start_time.year, e[0].start_time.month, e[0].start_time.day,
e[0].start_time.hour, e[0].start_time.minute))

self.assertEquals('MAXIMAL_ELONGATION', e[1].event_type)
self.assertEquals(1, len(e[1].objects))
self.assertEquals('VENUS', e[1].objects[0].skyfield_name)
self.assertEqual('46.1°', e[1].details)
self.assertEquals((2020, 3, 24, 21, 58), (e[1].start_time.year, e[1].start_time.month, e[1].start_time.day,
e[1].start_time.hour, e[1].start_time.minute))


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

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