Exemplo n.º 1
0
def output_topocentric_tests(dates):
    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)
    for (planet, code), (i, jd) in product(planets, enumerate(dates)):
        obj = novas.make_object(0, code, 'planet{}'.format(code), None)

        ra1, dec1, distance1 = call(novas.local_planet, jd, 0.0, obj, usno)
        ra2, dec2, distance2 = call(novas.topo_planet, jd, 0.0, obj, usno)
        alt, az = call(altaz_maneuver, jd, obj, usno)

        output(locals(), """\

        def test_{planet}_topocentric_date{i}():
            jd = JulianDate(tt={jd!r})
            usno = de405.earth.topos('38.9215 N', '77.0669 W', elevation_m=92.0)

            apparent = usno(jd).observe(de405.{planet}).apparent()
            ra, dec, distance = apparent.radec()
            compare(ra.hours, {ra1!r}, 0.001 * ra_arcsecond)
            compare(dec.degrees, {dec1!r}, 0.001 * arcsecond)

            ra, dec, distance = apparent.radec(epoch='date')
            compare(ra.hours, {ra2!r}, 0.001 * ra_arcsecond)
            compare(dec.degrees, {dec2!r}, 0.001 * arcsecond)

            alt, az, distance = apparent.altaz()
            compare(alt.degrees, {alt!r}, 0.001 * arcsecond)
            compare(az.degrees, {az!r}, 0.001 * arcsecond)

        """)
Exemplo n.º 2
0
def test_new_horizontal(timepairs, planets_list):
    """ Tests of generating a full position in horizontal coordinates. Uses
        fixtures to iterate through date pairs and planets to generate
        individual tests.
    """
    jd_tt = timepairs[0]
    delta_t = timepairs[1]
    planet_name = planets_list[0]
    planet_code = planets_list[1]
    position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
    ggr = coordinates.Topos('75 W', '45 N', 0.0,
                            temperature=10.0, pressure=1010.0)
    ggr.earth = emp.earth
    ggr.ephemeris = emp
    xp = yp = 0.0

    # replaces the for loop
    obj = c.make_object(0, planet_code, 'planet', None)
    ra, dec, dis = c.topo_planet(jd_tt, delta_t, obj, position)
    jd_ut1 = jd_tt - delta_t / 86400.0
    (zd, az), (ra, dec) = c.equ2hor(
        jd_ut1, delta_t, xp, yp, position, ra, dec, ref_option=0)
    planet = getattr(emp, planet_name)
    jd = JulianDate(tt=jd_tt, delta_t=delta_t)
    h = ggr(jd).observe(planet).apparent().horizontal()
    
    eq(zd * TAU / 360.0, h.zd, 0.001 * arcsecond)
    eq(az * TAU / 360.0, h.az, 0.001 * arcsecond)
    eq(0.25 * TAU - zd * TAU / 360.0, h.alt, 0.001 * arcsecond)
    eq(dis, h.distance, 0.001 * meter)
Exemplo n.º 3
0
def test_altaz(jd, planet_name_and_code):
    """ Tests of generating a full position in altaz coordinates. Uses
        fixtures to iterate through date pairs and planets to generate
        individual tests.
    """
    planet_name, planet_code = planet_name_and_code
    position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
    ggr = positionlib.Topos('45 N', '75 W', 0.0,
                            temperature=10.0, pressure=1010.0)
    ggr.ephemeris = de405
    xp = yp = 0.0

    obj = c.make_object(0, planet_code, 'planet', None)
    ra, dec, dis = c.topo_planet(jd.tt, jd.delta_t, obj, position)
    (zd0, az0), (ra, dec) = c.equ2hor(jd.ut1, jd.delta_t, xp, yp,
                                      position, ra, dec)
    alt0 = 90.0 - zd0

    planet = getattr(de405, planet_name)
    g = ggr(jd)
    distance = length_of((g - planet(jd)).position.AU)
    alt, az, d = g.observe(planet).apparent().altaz()

    eq(az0, az.degrees(), 0.001 * arcsecond_in_degrees)
    eq(alt0, alt.degrees(), 0.001 * arcsecond_in_degrees)
    eq(dis, distance, 0.5 * meter)
Exemplo n.º 4
0
 def _update_geo_loc(self):
     self._geo_loc = make_on_surface(self._latitude, 
                                     self._longitude, 
                                     self._height, 
                                     self._temperature,
                                     self._pressure
                                     )
def test_setup_LSST_location():

    test_site = make_on_surface(10.0, 10.0, 10.0, 10.0, 10.0)

    lsst = lsst_visibility_calculator.setup_LSST_location()

    assert type(lsst) == type(test_site)
    assert lsst.height == 2663.0
    assert lsst.latitude == -30.244639
    assert lsst.longitude == -70.749417
Exemplo n.º 6
0
def setup_LSST_location():
    """Function to build a NOVAS-compatible observatory descriptor for
    the LSST site"""

    height = 2663.0
    latitude = -30.244639
    longitude = -70.749417

    temperature = 10.0
    pressure = 750.0

    lsst = make_on_surface(latitude, longitude, height, temperature, pressure)

    return lsst
Exemplo n.º 7
0
    def test_topo_planet(self):
        position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
        ggr = coordinates.Topos('75 W', '45 N', 0.0,
                                temperature=10.0, pressure=1010.0)
        ggr.earth = self.e.earth
        ggr.ephemeris = self.e

        for (jd_tt, delta_t), name in product([P0, PA, PB], planets_to_test):

            obj = c.make_object(0, planet_codes[name], 'planet', None)
            ra, dec, dis = c.topo_planet(jd_tt, delta_t, obj, position)

            planet = getattr(self.e, name)
            jd = JulianDate(tt=jd_tt, delta_t=delta_t)
            g = ggr(jd).observe(planet).apparent()

            self.eq(ra * tau / 24.0, g.ra, 0.001 * arcsecond)
            self.eq(dec * tau / 360.0, g.dec, 0.001 * arcsecond)
            self.eq(dis, g.distance, 0.001 * meter)
Exemplo n.º 8
0
def test_topo_planet(jd, planet_name_and_code):
    position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
    ggr = positionlib.Topos('45 N', '75 W', 0.0,
                            temperature=10.0, pressure=1010.0)
    ggr.ephemeris = de405

    planet_name, planet_code = planet_name_and_code

    obj = c.make_object(0, planet_code, 'planet', None)
    ra0, dec0, distance0 = c.topo_planet(jd.tt, jd.delta_t, obj, position)

    planet = getattr(de405, planet_name)
    g = ggr(jd)
    distance = length_of((g - planet(jd)).position.AU)
    ra, dec, d = g.observe(planet).apparent().radec(epoch=jd)

    eq(ra0, ra.hours(), 0.001 * arcsecond_in_hours)
    eq(dec0, dec.degrees(), 0.001 * arcsecond_in_degrees)
    eq(distance0, distance, 0.5 * meter)
def output_topocentric_tests(dates):
    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)

    for (planet, code), (i, jd) in product(planets, enumerate(dates)):
        slug = slugify(planet)
        obj = novas.make_object(0, code, 'planet{0}'.format(code), None)

        ra1, dec1, distance1 = call(novas.local_planet, jd, 0.0, obj, usno)
        ra2, dec2, distance2 = call(novas.topo_planet, jd, 0.0, obj, usno)
        alt, az = call(altaz_maneuver, jd, usno, ra2, dec2)
        alt2, az2 = call(altaz_maneuver, jd, usno, ra2, dec2, 1)
        alt3, az3 = call(altaz_maneuver, jd, usno, ra2, dec2, 2)

        output(
            locals(), """\

        def test_{slug}_topocentric_date{i}(de405):
            t = load.timescale(delta_t=0.0).tt_jd({jd!r})
            earth = de405['earth']
            usno = earth + Topos('38.9215 N', '77.0669 W', elevation_m=92.0)

            apparent = usno.at(t).observe(de405[{planet!r}]).apparent()
            ra, dec, distance = apparent.radec()
            compare(ra.hours, {ra1!r}, 0.0005 * ra_arcsecond)
            compare(dec.degrees, {dec1!r}, 0.0005 * arcsecond)

            ra, dec, distance = apparent.radec(epoch='date')
            compare(ra.hours, {ra2!r}, 0.0005 * ra_arcsecond)
            compare(dec.degrees, {dec2!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz()
            compare(alt.degrees, {alt!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz('standard')
            compare(alt.degrees, {alt2!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az2!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz(10.0, 1010.0)
            compare(alt.degrees, {alt3!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az3!r}, 0.0005 * arcsecond)

        """)
Exemplo n.º 10
0
def output_topocentric_tests(dates):
    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)

    for (planet, code), (i, jd) in product(planets, enumerate(dates)):
        slug = slugify(planet)
        obj = novas.make_object(0, code, 'planet{0}'.format(code), None)

        ra1, dec1, distance1 = call(novas.local_planet, jd, 0.0, obj, usno)
        ra2, dec2, distance2 = call(novas.topo_planet, jd, 0.0, obj, usno)
        alt, az = call(altaz_maneuver, jd, usno, ra2, dec2)
        alt2, az2 = call(altaz_maneuver, jd, usno, ra2, dec2, 1)
        alt3, az3 = call(altaz_maneuver, jd, usno, ra2, dec2, 2)

        output(locals(), """\

        def test_{slug}_topocentric_date{i}(de405):
            t = load.timescale(delta_t=0.0).tt(jd={jd!r})
            earth = de405['earth']
            usno = earth.topos('38.9215 N', '77.0669 W', elevation_m=92.0)

            apparent = usno.at(t).observe(de405[{planet!r}]).apparent()
            ra, dec, distance = apparent.radec()
            compare(ra.hours, {ra1!r}, 0.0005 * ra_arcsecond)
            compare(dec.degrees, {dec1!r}, 0.0005 * arcsecond)

            ra, dec, distance = apparent.radec(epoch='date')
            compare(ra.hours, {ra2!r}, 0.0005 * ra_arcsecond)
            compare(dec.degrees, {dec2!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz()
            compare(alt.degrees, {alt!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz('standard')
            compare(alt.degrees, {alt2!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az2!r}, 0.0005 * arcsecond)

            alt, az, distance = apparent.altaz(10.0, 1010.0)
            compare(alt.degrees, {alt3!r}, 0.0005 * arcsecond)
            compare(az.degrees, {az3!r}, 0.0005 * arcsecond)

        """)
Exemplo n.º 11
0
def test_terra():
    epsilon = 1e-18

    observer = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)

    class Topos(object):
        latitude = 45.0 * DEG2RAD
        longitude = -75.0 * DEG2RAD
        elevation = 0.0
    topos = Topos()

    pos0, vel0 = array(c.terra(observer, 11.0))
    pos1, vel1 = array(c.terra(observer, 23.9))

    posn, veln = earthlib.terra(topos, array([11.0, 23.9]))

    eq(pos0, posn[:,0], epsilon)
    eq(pos1, posn[:,1], epsilon)
    eq(vel0, veln[:,0], epsilon)
    eq(vel1, veln[:,1], epsilon)
Exemplo n.º 12
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def output_topocentric_tests(dates):
    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)

    for (planet, code), (i, jd) in product(planets, enumerate(dates)):
        obj = novas.make_object(0, code, 'planet{}'.format(code), None)

        ra1, dec1, distance1 = call(novas.local_planet, jd, 0.0, obj, usno)
        ra2, dec2, distance2 = call(novas.topo_planet, jd, 0.0, obj, usno)
        alt, az = call(altaz_maneuver, jd, usno, ra2, dec2)
        alt2, az2 = call(altaz_maneuver, jd, usno, ra2, dec2, 1)
        alt3, az3 = call(altaz_maneuver, jd, usno, ra2, dec2, 2)

        output(
            locals(), """\

        def test_{planet}_topocentric_date{i}():
            jd = JulianDate(tt={jd!r})
            usno = de405.earth.topos('38.9215 N', '77.0669 W', elevation_m=92.0)

            apparent = usno(jd).observe(de405.{planet}).apparent()
            ra, dec, distance = apparent.radec()
            compare(ra.hours, {ra1!r}, 0.001 * ra_arcsecond)
            compare(dec.degrees, {dec1!r}, 0.001 * arcsecond)

            ra, dec, distance = apparent.radec(epoch='date')
            compare(ra.hours, {ra2!r}, 0.001 * ra_arcsecond)
            compare(dec.degrees, {dec2!r}, 0.001 * arcsecond)

            alt, az, distance = apparent.altaz()
            compare(alt.degrees, {alt!r}, 0.001 * arcsecond)
            compare(az.degrees, {az!r}, 0.001 * arcsecond)

            alt, az, distance = apparent.altaz('standard')
            compare(alt.degrees, {alt2!r}, 0.001 * arcsecond)
            compare(az.degrees, {az2!r}, 0.001 * arcsecond)

            alt, az, distance = apparent.altaz(10.0, 1010.0)
            compare(alt.degrees, {alt3!r}, 0.001 * arcsecond)
            compare(az.degrees, {az3!r}, 0.001 * arcsecond)

        """)
Exemplo n.º 13
0
def test_topo_planet(timepairs, planets_list):
    position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
    ggr = coordinates.Topos('75 W', '45 N', 0.0,
                            temperature=10.0, pressure=1010.0)
    ggr.earth = emp.earth
    ggr.ephemeris = emp

    jd_tt = timepairs[0]
    delta_t = timepairs[1]
    planet_name = planets_list[0]
    planet_code = planets_list[1]

    obj = c.make_object(0, planet_code, 'planet', None)
    ra, dec, dis = c.topo_planet(jd_tt, delta_t, obj, position)

    planet = getattr(emp, planet_name)
    jd = JulianDate(tt=jd_tt, delta_t=delta_t)
    g = ggr(jd).observe(planet).apparent()

    eq(ra * TAU / 24.0, g.ra, 0.001 * arcsecond)
    eq(dec * TAU / 360.0, g.dec, 0.001 * arcsecond)
    eq(dis, g.distance, 0.001 * meter)
Exemplo n.º 14
0
def test_terra():
    observer = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)

    # Note that this class stands in for a NOVAS Topos structure, but
    # not for our own Topos class!
    class Topos(object):
        latitude = 45.0 * DEG2RAD
        longitude = -75.0 * DEG2RAD
        elevation = 0.0
    topos = Topos()

    pos0, vel0 = array(c.terra(observer, 11.0))
    pos1, vel1 = array(c.terra(observer, 23.9))

    posn, veln = earthlib.terra(topos, array([11.0, 23.9]))

    epsilon = 1e-8 * meter  # 14 digits of agreement

    eq(pos0, posn[:,0], epsilon)
    eq(pos1, posn[:,1], epsilon)
    eq(vel0, veln[:,0], epsilon)
    eq(vel1, veln[:,1], epsilon)
Exemplo n.º 15
0
    def test_horizontal(self):
        position = c.make_on_surface(45.0, -75.0, 0.0, 10.0, 1010.0)
        ggr = coordinates.Topos('75 W', '45 N', 0.0,
                                temperature=10.0, pressure=1010.0)
        ggr.earth = self.e.earth
        ggr.ephemeris = self.e
        xp = yp = 0.0

        for (jd_tt, delta_t), name in product([P0, PA, PB], planets_to_test):
            obj = c.make_object(0, planet_codes[name], 'planet', None)
            ra, dec, dis = c.topo_planet(jd_tt, delta_t, obj, position)
            jd_ut1 = jd_tt - delta_t / 86400.0
            (zd, az), (ra, dec) = c.equ2hor(
                jd_ut1, delta_t, xp, yp, position, ra, dec, ref_option=0)

            planet = getattr(self.e, name)
            jd = JulianDate(tt=jd_tt, delta_t=delta_t)
            h = ggr(jd).observe(planet).apparent().horizontal()

            self.eq(zd * tau / 360.0, h.zd, 0.001 * arcsecond)
            self.eq(az * tau / 360.0, h.az, 0.001 * arcsecond)
            self.eq(0.25 * tau - zd * tau / 360.0, h.alt, 0.001 * arcsecond)
            self.eq(dis, h.distance, 0.001 * meter)
def output_subroutine_tests(dates):
    date_floats = [d for d in dates if not isinstance(d, list)]
    delta_t_floats = [+39.707, +57.1136, +63.8285, +66.7846]

    def shorter_cal_date(jd):
        y, m, d, h = novas.cal_date(jd)
        return y, m, d + h / 24.0 - 0.5

    for i, jd in enumerate(date_floats):
        cal_date = call(shorter_cal_date, jd)
        output(
            locals(), """\
            def test_calendar_date_{i}():
                compare(timelib.calendar_date({jd!r}), array({cal_date}), 0.0)
            """)

    for i, jd in enumerate(date_floats):
        angle = novas.era(jd)
        output(
            locals(), """\
            def test_earth_rotation_angle_date{i}():
                compare(earthlib.earth_rotation_angle({jd!r}) * 360.0, {angle!r},
                        0.000001 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        angles = novas.e_tilt(jd)
        output(
            locals(), """\
            def test_earth_tilt_date{i}(ts):
                compare(nutationlib.earth_tilt(ts.tdb_jd({jd!r})),
                        array({angles}), 0.00001 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        terms = novas.ee_ct(jd, 0.0, 0)
        output(
            locals(), """\
            def test_equation_of_the_equinoxes_complimentary_terms_date{i}():
                compare(nutationlib.equation_of_the_equinoxes_complimentary_terms({jd!r}),
                        array({terms!r}), 0.0000000000000001 * arcsecond)
            """)

    vector = (1.1, 1.2, 1.3)
    tie1 = novas.frame_tie(vector, 0)
    tie2 = novas.frame_tie(vector, -1)
    output(
        locals(), """\
        def test_forward_frame_tie():
            compare(framelib.ICRS_to_J2000.dot({vector}), {tie1}, 1e-15)

        def test_reverse_frame_tie():
            compare(framelib.ICRS_to_J2000.T.dot({vector}), {tie2}, 1e-15)
        """)

    for i, jd in enumerate(date_floats):
        jcentury = (jd - T0) / 36525.0
        arguments = novas.fund_args(jcentury)
        output(
            locals(), """\
            def test_fundamental_arguments_date{i}():
                compare(nutationlib.fundamental_arguments({jcentury!r}),
                        array({arguments}), 0.000000002 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        psi, eps = nutation_module.iau2000a(jd, 0.0)
        psi *= 1e7 / ASEC2RAD
        eps *= 1e7 / ASEC2RAD
        output(
            locals(), """\
            def test_iau2000a_date{i}():
                compare(nutationlib.iau2000a({jd!r}),
                        array([{psi!r}, {eps!r}]), 0.001)
            """)

    for i, jd in enumerate(date_floats):
        psi, eps = nutation_module.iau2000b(jd, 0.0)
        psi *= 1e7 / ASEC2RAD
        eps *= 1e7 / ASEC2RAD
        output(
            locals(), """\
            def test_iau2000b_date{i}():
                compare(nutationlib.iau2000b({jd!r}),
                        array([{psi!r}, {eps!r}]), 0.001)
            """)

    for i, args in enumerate([
        (-4712, 1, 1, 0.0),
        (-4712, 3, 1, 0.0),
        (-4712, 12, 31, 0.5),
        (-241, 3, 25, 19.0),
        (530, 9, 27, 23.5),
        (1976, 3, 7, 12.5),
        (2000, 1, 1, 0.0),
    ]):
        jd = novas.julian_date(*args)
        output(
            locals(), """\
            def test_julian_date_function_date{i}():
                compare(timelib.julian_date{args}, {jd!r}, 0.0)
            """)

    for i, jd in enumerate(date_floats):
        angle = novas.mean_obliq(jd)
        output(
            locals(), """\
            def test_mean_obliquity_date{i}():
                compare(nutationlib.mean_obliquity({jd!r}),
                        {angle!r}, 0.0)  # arcseconds
            """)

    for i, jd in enumerate(date_floats):
        vector = [1.1, 1.2, 1.3]
        result = nutation_function(jd, vector)
        output(
            locals(), """\
            def test_nutation_date{i}(ts):
                matrix = nutationlib.compute_nutation(ts.tdb_jd({jd!r}))
                result = einsum('ij...,j...->i...', matrix, [1.1, 1.2, 1.3])
                compare({result},
                        result, 1e-14)
            """)

    for i, jd in enumerate(date_floats):
        vector = [1.1, 1.2, 1.3]
        result = novas.precession(T0, vector, jd)
        output(
            locals(), """\
            def test_precession_date{i}():
                matrix = precessionlib.compute_precession({jd!r})
                result = einsum('ij...,j...->i...', matrix, [1.1, 1.2, 1.3])
                compare({result},
                        result, 1e-15)
            """)

    for i, jd in enumerate(date_floats):
        result1 = novas.sidereal_time(jd, 0.0, 0.0, False, True)
        result2 = novas.sidereal_time(jd, 0.0, 99.9, False, True)
        output(
            locals(), """\
            def test_sidereal_time_on_date{i}():
                jd = load.timescale(delta_t=0.0).tt_jd({jd!r})
                compare(earthlib.sidereal_time(jd), {result1!r}, 1e-13)

            def test_sidereal_time_with_nonzero_delta_t_on_date{i}():
                jd = load.timescale(delta_t=99.9).tt_jd({jd!r} + 99.9 * one_second)
                compare(earthlib.sidereal_time(jd), {result2!r}, 1e-13)
            """)

    p, v = novas.starvectors(
        novas.make_cat_entry('POLARIS', 'HIP', 0, 2.530301028, 89.264109444,
                             44.22, -11.75, 7.56, -17.4))
    output(
        locals(), """\
        def test_star_vector():
            star = starlib.Star(ra_hours=2.530301028, dec_degrees=89.264109444,
                                ra_mas_per_year=44.22, dec_mas_per_year=-11.75,
                                parallax_mas=7.56, radial_km_per_s=-17.4)
            star.au_km = OLD_AU_KM
            star._compute_vectors()
            compare(star._position_au,
                    {p!r},
                    1e3 * meter)
            compare(star._velocity_au_per_d,
                    {v!r},
                    1e-3 * meter)  # TODO: was 1e-6 before switch to modern au
        """)

    atp = product([-5, -1, 15, 89.95], [10, 25], [1010, 1013.25])

    for i, (angle, temperature, pressure) in enumerate(atp):
        location = novas.make_on_surface(0.0, 0.0, 0, temperature, pressure)
        r = novas.refract(location, 90 - angle, 2)
        output(
            locals(), """\
            def test_refraction{i}():
                r = earthlib.refraction({angle}, {temperature}, {pressure})
                compare(r, {r!r}, 1e-9 * arcsecond)
            """)

    northpole = novas.make_on_surface(90.0, 0.0, 0.0, 10.0, 1010.0)

    for i, angle in enumerate([-90, -2, -1, 0, 1, 3, 9, 90]):
        alt, az = altaz_maneuver(T0, northpole, 0.0, angle, ref=2)
        output(
            locals(), """\
            def test_refract{i}():
                alt = earthlib.refract({angle!r}, 10.0, 1010.0)
                compare(alt, {alt!r}, 1e-9 * arcsecond)
            """)

    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)

    ra = 12.34
    for i, (tt, dec) in enumerate(product(date_floats, [56.78, -67.89])):
        alt, az = altaz_maneuver(tt, usno, ra, dec, ref=0)
        output(
            locals(), """\
            def test_from_altaz_{i}(earth):
                jd = load.timescale(delta_t=0.0).tt_jd({tt!r})
                usno = earth + Topos(
                    '38.9215 N', '77.0669 W', elevation_m=92.0)
                a = usno.at(jd).from_altaz(alt_degrees={alt!r}, az_degrees={az!r})
                ra, dec, distance = a.radec(epoch=jd)
                compare(ra.hours, {ra!r}, 1e-9 * arcsecond)
                compare(dec.degrees, {dec!r}, 1e-9 * arcsecond)
            """)

    for i, (tt, delta_t) in enumerate(zip(date_floats, delta_t_floats)):
        jd_low = xp = yp = 0.0
        vector = [1.1, 1.2, 1.3]
        ut1 = tt - delta_t * one_second
        result = novas.ter2cel(ut1, jd_low, delta_t, xp, yp, vector)
        output(
            locals(), """\
            def test_ITRF_to_GCRS_conversion_on_date{i}():
                jd = load.timescale(delta_t={delta_t!r}).tt_jd({tt!r})
                position = positionlib.ITRF_to_GCRS(jd, {vector!r})
                compare(position, {result!r}, 1e-13)
            """)

    for i, jd_tdb in enumerate(date_floats):
        result = novas.tdb2tt(jd_tdb)[1]
        output(
            locals(), """\
            def test_tdb_minus_tt_on_date{i}():
                result = timelib.tdb_minus_tt({jd_tdb!r})
                compare(result, {result!r}, 1e-16)
            """)
Exemplo n.º 17
0
def output_subroutine_tests(dates):
    date_floats = [d for d in dates if not isinstance(d, list)]
    delta_t_floats = [+39.707, +57.1136, +63.8285, +66.7846]

    def shorter_cal_date(jd):
        y, m, d, h = novas.cal_date(jd)
        return y, m, d + h / 24.0 - 0.5

    for i, jd in enumerate(date_floats):
        cal_date = call(shorter_cal_date, jd)
        output(locals(), """\
            def test_calendar_date_{i}():
                compare(timelib.calendar_date({jd!r}), array({cal_date}), 0.0)
            """)

    for i, jd in enumerate(date_floats):
        angle = novas.era(jd)
        output(locals(), """\
            def test_earth_rotation_angle_date{i}():
                compare(earthlib.earth_rotation_angle({jd!r}) * 360.0, {angle},
                        0.000001 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        angles = novas.e_tilt(jd)
        output(locals(), """\
            def test_earth_tilt_date{i}():
                compare(nutationlib.earth_tilt(JulianDate(tdb={jd!r})),
                        array({angles}), 0.00001 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        terms = novas.ee_ct(jd, 0.0, 0)
        output(locals(), """\
            def test_equation_of_the_equinoxes_complimentary_terms_date{i}():
                compare(nutationlib.equation_of_the_equinoxes_complimentary_terms({jd!r}),
                        array({terms}), 0.0000000000000001 * arcsecond)
            """)

    vector = (1.1, 1.2, 1.3)
    tie1 = novas.frame_tie(vector, 0)
    tie2 = novas.frame_tie(vector, -1)
    output(locals(), """\
        def test_forward_frame_tie():
            compare(framelib.ICRS_to_J2000.dot({vector}), {tie1}, 1e-15)

        def test_reverse_frame_tie():
            compare(framelib.ICRS_to_J2000.T.dot({vector}), {tie2}, 1e-15)
        """)

    for i, jd in enumerate(date_floats):
        jcentury = (jd - T0) / 36525.0
        arguments = novas.fund_args(jcentury)
        output(locals(), """\
            def test_fundamental_arguments_date{i}():
                compare(nutationlib.fundamental_arguments({jcentury!r}),
                        array({arguments}), 0.000000002 * arcsecond)
            """)

    for i, jd in enumerate(date_floats):
        psi, eps = nutation_module.iau2000a(jd, 0.0)
        psi *= 1e7 / ASEC2RAD
        eps *= 1e7 / ASEC2RAD
        output(locals(), """\
            def test_iau2000a_date{i}():
                compare(nutationlib.iau2000a({jd!r}),
                        array([{psi}, {eps}]), 0.001)
            """)

    for i, args in enumerate([
          (-4712, 1, 1, 0.0),
          (-4712, 3, 1, 0.0),
          (-4712, 12, 31, 0.5),
          (-241, 3, 25, 19.0),
          (530, 9, 27, 23.5),
          (1976, 3, 7, 12.5),
          (2000, 1, 1, 0.0),
          ]):
        jd = novas.julian_date(*args)
        output(locals(), """\
            def test_julian_date_function_date{i}():
                compare(timelib.julian_date{args}, {jd!r}, 0.0)
            """)

    for i, jd in enumerate(date_floats):
        angle = novas.mean_obliq(jd)
        output(locals(), """\
            def test_mean_obliquity_date{i}():
                compare(nutationlib.mean_obliquity({jd!r}),
                        {angle!r}, 0.0)  # arcseconds
            """)

    for i, jd in enumerate(date_floats):
        vector = [1.1, 1.2, 1.3]
        result = nutation_function(jd, vector)
        output(locals(), """\
            def test_nutation_date{i}():
                matrix = nutationlib.compute_nutation(JulianDate(tdb={jd!r}))
                result = einsum('ij...,j...->i...', matrix, [1.1, 1.2, 1.3])
                compare({result},
                        result, 1e-14)
            """)

    for i, jd in enumerate(date_floats):
        vector = [1.1, 1.2, 1.3]
        result = novas.precession(T0, vector, jd)
        output(locals(), """\
            def test_precession_date{i}():
                matrix = precessionlib.compute_precession({jd!r})
                result = einsum('ij...,j...->i...', matrix, [1.1, 1.2, 1.3])
                compare({result},
                        result, 1e-15)
            """)

    for i, jd in enumerate(date_floats):
        result1 = novas.sidereal_time(jd, 0.0, 0.0, False, True)
        result2 = novas.sidereal_time(jd, 0.0, 99.9, False, True)
        output(locals(), """\
            def test_sidereal_time_on_date{i}():
                jd = JulianDate(tt={jd!r})
                compare(earthlib.sidereal_time(jd), {result1!r}, 1e-13)

            def test_sidereal_time_with_nonzero_delta_t_on_date{i}():
                jd = JulianDate(tt={jd!r} + 99.9 * one_second, delta_t=99.9)
                compare(earthlib.sidereal_time(jd), {result2!r}, 1e-13)
            """)

    p, v = novas.starvectors(novas.make_cat_entry(
        'POLARIS', 'HIP', 0, 2.530301028, 89.264109444,
        44.22, -11.75, 7.56, -17.4))
    output(locals(), """\
        def test_star_vector():
            star = starlib.Star(ra_hours=2.530301028, dec_degrees=89.264109444,
                                ra_mas_per_year=44.22, dec_mas_per_year=-11.75,
                                parallax_mas=7.56, radial_km_per_s=-17.4)
            star.au_km = de405.jplephemeris.AU
            star._compute_vectors()
            compare(star._position_au,
                    {p!r},
                    1e3 * meter)
            compare(star._velocity_au_per_d,
                    {v!r},
                    1e-3 * meter)  # TODO: was 1e-6 before switch to modern au
        """)

    atp = product([-5, -1, 15, 89.95], [10, 25], [1010, 1013.25])

    for i, (angle, temperature, pressure) in enumerate(atp):
        location = novas.make_on_surface(0.0, 0.0, 0, temperature, pressure)
        r = novas.refract(location, 90 - angle, 2)
        output(locals(), """\
            def test_refraction{i}():
                r = earthlib.refraction({angle}, {temperature}, {pressure})
                compare(r, {r}, 0.001 * arcsecond)
            """)

    northpole = novas.make_on_surface(90.0, 0.0, 0.0, 10.0, 1010.0)

    for i, angle in enumerate([-90, -2, -1, 0, 1, 3, 9, 90]):
        alt, az = altaz_maneuver(T0, northpole, 0.0, angle, ref=2)
        output(locals(), """\
            def test_refract{i}():
                alt = earthlib.refract({angle!r}, 10.0, 1010.0)
                compare(alt, {alt!r}, 0.000000001 * arcsecond)
            """)

    usno = novas.make_on_surface(38.9215, -77.0669, 92.0, 10.0, 1010.0)

    ra = 12.34
    for i, (tt, dec) in enumerate(product(date_floats, [56.78, -67.89])):
        alt, az = altaz_maneuver(tt, usno, ra, dec, ref=0)
        output(locals(), """\
            def test_from_altaz_{i}():
                jd = JulianDate(tt={tt!r})
                usno = de405.earth.topos(
                    '38.9215 N', '77.0669 W', elevation_m=92.0)
                a = usno(jd).from_altaz(alt_degrees={alt!r}, az_degrees={az!r})
                ra, dec, distance = a.radec(epoch=jd)
                compare(ra.hours, {ra!r}, 0.000000001 * arcsecond)
                compare(dec.degrees, {dec!r}, 0.000000001 * arcsecond)
            """)

    for i, (tt, delta_t) in enumerate(zip(date_floats, delta_t_floats)):
        jd_low = xp = yp = 0.0
        vector = [1.1, 1.2, 1.3]
        ut1 = tt - delta_t * one_second
        result = novas.ter2cel(ut1, jd_low, delta_t, xp, yp, vector)
        output(locals(), """\
            def test_ITRF_to_GCRS_conversion_on_date{i}():
                jd = JulianDate(tt={tt!r}, delta_t={delta_t!r})
                position = positionlib.ITRF_to_GCRS(jd, {vector!r})
                compare(position, {result!r}, 1e-13)
            """)

    for i, jd_tdb in enumerate(date_floats):
        result = novas.tdb2tt(jd_tdb)[1]
        output(locals(), """\
            def test_tdb_minus_tt_on_date{i}():
                result = timelib.tdb_minus_tt({jd_tdb!r})
                compare(result, {result!r}, 1e-16)
            """)
Exemplo n.º 18
0
#tt-ut1
delta_t = tt_tai + leap_second - ut1_utc
#构造不同的儒略日时间变量
jd_utc = novas.julian_date(year, month, day, hour)  #utc
jd_ut1 = jd_utc + ut1_utc / 86400.0  #ut1
jd_tt = jd_utc + (leap_second + tt_tai) / 86400.0  #tt
jd = (jd_tt, 0.0)
jd0 = (jd_tt - ta / 86400, 0.0)
#打开de历表
jd_s, jd_e, num = eph_manager.ephem_open()
#太阳和地球构造
sun = novas.make_object(0, 10, 'sun', None)
moon = novas.make_object(0, 11, 'moon', None)
earth = novas.make_object(0, 3, 'earth', None)
#位置构造
location1 = novas.make_on_surface(latitude, longitude, height, 25.0, 1013)
location = novas.make_observer_on_surface(latitude, longitude, height, 25.0,
                                          1013)
#矢量和夹角初始化
O1_S1 = [0.0, 0.0, 0.0]  #月球半影锥点到太阳质心矢量坐标
O2_S1 = [0.0, 0.0, 0.0]  #月球全影锥点到太阳质心矢量坐标
O1_E = [0.0, 0.0, 0.0]  #月球半影锥点到地心距离矢量坐标
O1_T = [0.0, 0.0, 0.0]  #月球半影锥点到地球某一点距离矢量坐标
O2_E = [0.0, 0.0, 0.0]  #月球全影锥点到地心距离矢量坐标
O2_T = [0.0, 0.0, 0.0]  #月球全影锥点到地球某一点距离矢量坐标
O1_M = [0.0, 0.0, 0.0]  #月球半影锥点到月心距离矢量坐标
O2_M = [0.0, 0.0, 0.0]  #月球全影锥点到月心距离矢量坐标
E_O4 = [0.0, 0.0, 0.0]
#经纬度转为ITRS下坐标
E_T=[re*math.cos(latitude*constants.DEG2RAD)*math.cos(longitude*constants.DEG2RAD),\
  re*math.cos(latitude*constants.DEG2RAD)*math.sin(longitude*constants.DEG2RAD),\