def test_time_comparisons(self):
"""Test ordering transform.Time instances."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
t1 = transform.Time((56300, 5026000), format='MCS')
t2 = transform.Time(1357608224.0, format='TIMET')
self.assertTrue(t0 < t1)
self.assertTrue(t0 > t2)
self.assertTrue(t2 != t1)
def test_time_init(self):
"""Test the transform.Time constructor."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
str(t0)
repr(t0)
self.assertEqual(t0.utc_str, '2013-01-08 01:23:45.000')
self.assertEqual(t0.utc_mcs, (56300, 5025000))
self.assertAlmostEqual(t0.utc_dp / 196e6, 1357608225.0, 3)
t1 = transform.Time((56300, 5026000), format='MCS')
self.assertEqual(t1.utc_str, '2013-01-08 01:23:46.000')
self.assertAlmostEqual(t1.utc_dp / 196e6, 1357608226.0, 3)
t2 = transform.Time(1357608224.0, format='TIMET')
self.assertEqual(t2.utc_str, '2013-01-08 01:23:44.000')
self.assertEqual(t2.utc_mcs, (56300, 5024000))
t3 = transform.Time('2013-01-08 01:23:45.000', format='STR')
t3.utc_mcs = (56300, 5024000)
self.assertEqual(t3.utc_str, '2013-01-08 01:23:44.000')
def test_planetaryposition_jupiter(self):
"""Test the location of Jupiter."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
obs = lwa1.get_observer()
obs.date = t0.utc_str
jove = ephem.Jupiter()
jove.compute(obs)
p0 = transform.PlanetaryPosition('Jupiter')
self.assertAlmostEqual(
p0.apparent_equ(t0)[0], jove.g_ra * 180.0 / math.pi, 4)
self.assertAlmostEqual(
p0.apparent_equ(t0)[1], jove.g_dec * 180.0 / math.pi, 4)
def test_planetaryposition_saturn(self):
"""Test the location of Saturn."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
obs = lwa1.get_observer()
obs.date = t0.utc_str
sat = ephem.Saturn()
sat.compute(obs)
p0 = transform.PlanetaryPosition('Saturn')
self.assertAlmostEqual(
p0.apparent_equ(t0)[0], sat.g_ra * 180.0 / math.pi, 4)
self.assertAlmostEqual(
p0.apparent_equ(t0)[1], sat.g_dec * 180.0 / math.pi, 4)
def test_geographicalposition_lst(self):
"""Test the tranform.GeographicalPosition sidereal time."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
lon = lwa1.long * 180.0 / math.pi
lat = lwa1.lat * 180.0 / math.pi
elv = lwa1.elev
obs = lwa1.get_observer()
g0 = transform.GeographicalPosition([lon, lat, elv])
# The astro.get_apparent_sidereal_time() function doesn't care about
# elevation
obs.elev = 0.0
obs.date = t0.utc_str
self.assertAlmostEqual(g0.sidereal(t0),
obs.sidereal_time() * 12.0 / math.pi, 4)
def test_pointingdirection_azalt(self):
"""Test the transform.PointingDirection az/alt transform."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
lon = lwa1.long * 180.0 / math.pi
lat = lwa1.lat * 180.0 / math.pi
elv = lwa1.elev
obs = lwa1.get_observer()
obs.date = t0.utc_str
jove = ephem.Jupiter()
jove.compute(obs)
g0 = transform.GeographicalPosition([lon, lat, elv])
p0 = transform.PlanetaryPosition('Jupiter')
d0 = transform.PointingDirection(p0, g0)
str(d0)
repr(d0)
self.assertAlmostEqual(d0.hrz(t0)[0], jove.az * 180.0 / math.pi, 0)
self.assertAlmostEqual(d0.hrz(t0)[1], jove.alt * 180.0 / math.pi, 0)
def test_pointingdirection_rst(self):
"""Test the transform.PointingDirection az/alt transform."""
t0 = transform.Time('2013-01-08 01:23:45.000', format='STR')
lon = lwa1.long * 180.0 / math.pi
lat = lwa1.lat * 180.0 / math.pi
elv = lwa1.elev
obs = lwa1.get_observer()
obs.date = t0.utc_str
jove = ephem.Jupiter()
jove.compute(obs)
g0 = transform.GeographicalPosition([lon, lat, elv])
p0 = transform.PlanetaryPosition('Jupiter')
d0 = transform.PointingDirection(p0, g0)
rst = d0.rst(t0)
self.assertAlmostEqual(rst.rise,
obs.next_rising(jove) * 1.0 + DJD_OFFSET, 2)
self.assertAlmostEqual(rst.transit,
obs.next_transit(jove) * 1.0 + DJD_OFFSET, 2)
self.assertAlmostEqual(rst.set,
obs.next_setting(jove) * 1.0 + DJD_OFFSET, 2)
