Esempio n. 1
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    def test_angular_separation(self):
        time = sunset_and_rise_for_date(self.data, 2020, 12, 17)[0]

        moon = self.data.ephemeris['moon']
        mercury = self.data.get_body("Mercury")

        sep, pos = angular_separation(self.data, moon, mercury, time)
        self.assertLessEqual(abs(sep.degrees - 39.1), 1.0)
        self.assertEqual(pos, EclipticPosition.BEHIND)

        sep, pos = angular_separation(self.data, mercury, moon, time)
        self.assertEqual(pos, EclipticPosition.AHEAD)
        self.assertLessEqual(abs(sep.degrees - 39.1), 1.0)

        dablin = Star.from_dataframe(self.data.stars.loc[100345])
        sep, pos = angular_separation(self.data, moon, dablin, time)
        self.assertEqual(pos, EclipticPosition.BELOW)
        self.assertLessEqual(abs(sep.degrees - 8.9), 1.0)

        sep, pos = angular_separation(self.data, dablin, moon, time)
        self.assertEqual(pos, EclipticPosition.ABOVE)
        self.assertLessEqual(abs(sep.degrees - 8.9), 1.0)

        fomalhaut = Star.from_dataframe(self.data.stars.loc[113368])
        sep, pos = angular_separation(self.data, fomalhaut, mercury, time)
        self.assertEqual(pos, EclipticPosition.BEHIND)
        self.assertLessEqual(abs(sep.degrees - 70.45), 1.0)

        sep, pos = angular_separation(self.data, mercury, fomalhaut, time)
        self.assertEqual(pos, EclipticPosition.AHEAD)
        self.assertLessEqual(abs(sep.degrees - 70.45), 1.0)
Esempio n. 2
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def parse(line):
    """Return a `Star` build by parsing a Hipparcos catalog entry `line`."""
    # See ftp://cdsarc.u-strasbg.fr/cats/I/239/ReadMe
    star = Star(
        ra=Angle(degrees=float(line[51:63])),
        dec=Angle(degrees=float(line[64:76])),
        ra_mas_per_year=float(line[87:95]),
        dec_mas_per_year=float(line[96:104]),
        parallax_mas=float(line[79:86]),
        names=[('HIP', int(line[8:14]))],
        )
    star._position_au += star._velocity_au_per_d * days
    distance, dec, ra = to_polar(star._position_au)
    star.ra = Angle(radians=ra, preference='hours')
    star.dec = Angle(radians=dec)
    return star
def test_cirs_sofa():
    ts = api.load.timescale()
    earth = api.load('de421.bsp')['earth']

    test_data = [
        [45.0, 46.0, 2458327],
        [200.0, -22.0, 2458327],
        [45.0, 46.0, 2459327]
    ]

    # Results output by SOFA. Calculated using the source code above.
    sofa_results = [
        [45.074343838325, 46.067831092355],
        [200.013551320030,  -22.096008994214],
        [45.077698288877,  46.082296559677]
    ]

    tol = 1e-5 / 3600.0  # 10 micro arc-seconds

    for ((ra_icrs, dec_icrs, tdb), (ra_sofa, dec_sofa)) in zip(test_data, sofa_results):
        ss = Star(ra_hours=(ra_icrs / 15.0), dec_degrees=dec_icrs)
        st = ts.tdb(jd=tdb)
        with low_precision_ERA():
            ra_cirs, dec_cirs, _ = earth.at(st).observe(ss).apparent().cirs_radec(st)

        assert np.allclose(ra_cirs._degrees, ra_sofa, rtol=0.0, atol=tol)
        assert np.allclose(dec_cirs._degrees, dec_sofa, rtol=0.0, atol=tol)
Esempio n. 4
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def parse(line):
    "DEPRECATED; see :func:`~skyfield.data.hipparcos.load_dataframe() instead."
    # See ftp://cdsarc.u-strasbg.fr/cats/I/239/ReadMe
    star = Star(
        ra=Angle(degrees=float(line[51:63])),
        dec=Angle(degrees=float(line[64:76])),
        ra_mas_per_year=float(line[87:95]),
        dec_mas_per_year=float(line[96:104]),
        parallax_mas=float(line[79:86]),
        names=[('HIP', int(line[8:14]))],
    )
    star._position_au += star._velocity_au_per_d * days
    distance, dec, ra = to_polar(star._position_au)
    star.ra = Angle(radians=ra, preference='hours')
    star.dec = Angle(radians=dec)
    return star
Esempio n. 5
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def run(location, t, target):
    """
    Assumes location is dict with "latitude", "longitude" keys in decimal degres, and "elevation" key in meters
    Assumes t is datetime obj
    Assumes target is astropy SkyCoord with ICRS RA and DE
    """

    planets = load("de421.bsp")
    earth = planets["earth"]
    moon = planets["moon"]

    # convert from astropy SkyCoord to skyfield "Star"
    target = Star(ra_hours=target.ra.hour, dec_degrees=target.dec.degree)

    loc = earth + Topos(location["latitude"],
                        location["longitude"],
                        elevation_m=location["elevation"])

    moon_app_pos = loc.at(t).observe(moon).apparent()

    app_pos = loc.at(t).observe(target).apparent()

    alt, _, _ = app_pos.altaz()
    alt = alt.degrees  # convert from skyfield.units.Angle to float degrees

    moondiff = moon_app_pos.separation_from(app_pos).degrees

    return alt, moondiff
Esempio n. 6
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def parse(line):
    "DEPRECATED; see :func:`~skyfield.data.hipparcos.load_dataframe() instead."
    # See ftp://cdsarc.u-strasbg.fr/cats/I/239/ReadMe
    star = Star(
        ra=Angle(degrees=float(line[51:63])),
        dec=Angle(degrees=float(line[64:76])),
        ra_mas_per_year=float(line[87:95]),
        dec_mas_per_year=float(line[96:104]),
        parallax_mas=float(line[79:86]),
        names=[('HIP', int(line[8:14]))],
        )
    star._position_au += star._velocity_au_per_d * days
    distance, dec, ra = to_polar(star._position_au)
    star.ra = Angle(radians=ra, preference='hours')
    star.dec = Angle(radians=dec)
    return star
Esempio n. 7
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def parse(line):
    """Return a `Star` build by parsing a Hipparcos catalog entry `line`."""
    # See ftp://cdsarc.u-strasbg.fr/cats/I/239/ReadMe
    star = Star(
        ra=Angle(degrees=float(line[51:63])),
        dec=Angle(degrees=float(line[64:76])),
        ra_mas_per_year=float(line[87:95]),
        dec_mas_per_year=float(line[96:104]),
        parallax_mas=float(line[79:86]),
        names=[('HIP', int(line[8:14]))],
    )
    star._position_au += star._velocity_au_per_d * days
    distance, dec, ra = to_polar(star._position_au)
    star.ra = Angle(radians=ra, preference='hours')
    star.dec = Angle(radians=dec)
    return star
Esempio n. 8
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    def star(self,
             ref: Union[str, int],
             culture: Optional[str] = None) -> CelestialObject:
        """Fetch a star by its name or Hipparcos catalogue number.

        Args:
            ref: Either the string common name, or the int catalogue number, e.g. 87937 for
                Barnard's Star.
            culture: If given, use as a hint to understand the common name.
        """
        number = ref if isinstance(ref, int) else self.starNumber(ref)
        data = self._stars.loc[number]
        names = self._starNames.allNames(number)
        primaryName = (ref if isinstance(ref, str) else names["western"]
                       if "western" in names else names["hip"])
        star = Star.from_dataframe(data)
        return makeObject(
            type=ObjectType.STAR,
            name=primaryName,
            position=star,
            dataFrame=data,
            names=names,
        )
Esempio n. 9
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    def get_body(self, name: str):
        name = name.lower()

        if name == MERCURY.name:
            return self.ephemeris["MERCURY BARYCENTER"]
        if name == VENUS.name:
            return self.ephemeris["VENUS BARYCENTER"]
        if name == EARTH:
            return self.ephemeris["EARTH"]
        if name == MARS.name:
            return self.ephemeris["MARS BARYCENTER"]
        if name == SATURN.name:
            return self.ephemeris["SATURN BARYCENTER"]
        if name == JUPITER.name:
            return self.ephemeris["JUPITER BARYCENTER"]
        if name == MOON:
            return self.ephemeris["MOON"]
        if name == SUN:
            return self.ephemeris["SUN"]

        if name == ALCYONE:
            return Star.from_dataframe(self.stars.loc[17702])
        if name == ANTARES:
            return Star.from_dataframe(self.stars.loc[80763])
        if name == BETA_CAPRICORNI:
            return Star.from_dataframe(self.stars.loc[100345])
        if name == BETA_GEMINORUM:
            return Star.from_dataframe(self.stars.loc[37826])
        if name == BETA_LIBRAE:
            return Star.from_dataframe(self.stars.loc[74785])
        if name == BETA_VIRGINIS:
            return Star.from_dataframe(self.stars.loc[57757])
        if name == EPSILON_LEONIS:
            return Star.from_dataframe(self.stars.loc[47908])
        if name == EPSILON_PISCIUM:
            return Star.from_dataframe(self.stars.loc[4906])
        if name == FORTY_TWO_CANCRI:
            return Star.from_dataframe(self.stars.loc[42578])
        if name == REGULUS:
            return Star.from_dataframe(self.stars.loc[49669])
        if name == THETA_LEONIS:
            return Star.from_dataframe(self.stars.loc[54879])
        if name == SHERATAN:
            return Star.from_dataframe(self.stars.loc[8903])

        if name == NU_ARIETIS:
            return Star.from_dataframe(self.stars.loc[12332])
        if name == NU_AURIGAE:
            return Star.from_dataframe(self.stars.loc[27673])
        if name == THETA_CANCRI:
            return Star.from_dataframe(self.stars.loc[41822])
        if name == ETA_CAPRICORNI:
            return Star.from_dataframe(self.stars.loc[104019])
        if name == OMEGA_GEMINORUM:
            return Star.from_dataframe(self.stars.loc[33927])
        if name == FIFTY_TWO_LEONIS:
            return Star.from_dataframe(self.stars.loc[52689])
        if name == NU_LIBRAE:
            return Star.from_dataframe(self.stars.loc[73945])
        if name == THIRTY_SIX_PERSEI:
            return Star.from_dataframe(self.stars.loc[16499])
        if name == FIFTY_EIGHT_PISCIUM:
            return Star.from_dataframe(self.stars.loc[3675])
        if name == ASCELLA:
            return Star.from_dataframe(self.stars.loc[93506])
        if name == EPSILON_TAURI:
            return Star.from_dataframe(self.stars.loc[20889])
        if name == THETA_VIRGINIS:
            return Star.from_dataframe(self.stars.loc[64238])

        raise ValueError