def test_distance(self):
# http://www.astronomycafe.net/qadir/q1890.html (Sten Odenwald)
coords1 = Coordinates(100.2, -16.58)
coords2 = Coordinates(87.5, 7.38)
distance = coords1.distance(coords2)
self.assertAlmostEqual(distance, 27.054384870767787)
# http://www.skythisweek.info/angsep.pdf (David Oesper)
coords3 = Coordinates(165.458, 56.3825)
coords4 = Coordinates(165.933, 61.7511)
distance = coords3.distance(coords4)
self.assertAlmostEqual(distance, 5.374111607543190)
def test_distance(self):
# http://www.astronomycafe.net/qadir/q1890.html (Sten Odenwald)
coords1 = Coordinates(100.2, -16.58)
coords2 = Coordinates(87.5, 7.38)
distance = coords1.distance(coords2)
self.assertAlmostEqual(distance, 27.054384870767787)
# http://www.skythisweek.info/angsep.pdf (David Oesper)
coords3 = Coordinates(165.458, 56.3825)
coords4 = Coordinates(165.933, 61.7511)
distance = coords3.distance(coords4)
self.assertAlmostEqual(distance, 5.374111607543190)
def random(cls):
""" Return a random Coordinates object """
ra = random.uniform(*cls.RIGHT_ASCENSION_RANGE)
dec = random.uniform(*cls.DECLINATION_RANGE)
# Use None for both 'pm_ra' and 'pm_dec' or none of them. If does not
# make much sense to know the proper motion in declination but not in
# right ascension, or vice versa.
if random.choice([True, False]):
pm_ra = cls.get_random_pm(cls.PM_RA_RANGE)
pm_dec = cls.get_random_pm(cls.PM_DEC_RANGE)
else:
pm_ra = pm_dec = None
return Coordinates(ra, dec, pm_ra, pm_dec)
class LoadCoordinatesTest(unittest.TestCase):
# A series of two-element tuples, one per line. The first element is a
# string containing the name of an astronomical object. The second is a
# four-element tuple with the right ascension, declination and proper
# motions. Nones are used if the proper motions are not known.
TEST_DATA_DIR = "./test/test_data/SIMBAD_objects"
# Parse the SIMBAD file and map each astronomical object (a string) to
# its right ascension and declination (an astromatic.Coordinates object)
COORDINATES = {}
with open(TEST_DATA_DIR, "rt") as fd:
for line in fd:
line = line.strip()
if line and not line.startswith("#"):
object_, coords = eval(line)
COORDINATES[object_] = Coordinates(*coords)
NCOORDS = (1, len(COORDINATES)) # number of objects in each file
NEMPTY = (1, 50) # minimum and maximum number of empty lines
NCOMMENTS = (1, 50) # minimum and maximum number of comment lines
COMMENT_PROB = 0.35 # probability of inline comments
SEPS = [" ", "\t"] # separators randomly added to the coords file
MAX_SEPS = 5 # maximum number of consecutive separators
@classmethod
def get_seps(cls, minimum):
"""Return a string containing a random number of separators.
The separators are randomly chosen from cls.SEPS. The returned string
contains N of them, where N is a random integer such that: minimum <=
N <= cls.MAX_SEPS.
"""
n = random.randint(minimum, cls.MAX_SEPS)
return "".join(random.choice(cls.SEPS) for _ in range(n))
@classmethod
def get_comment(cls):
""" Return a random string that starts with '#'. """
# Use the name of one of the SIMBAD objects
object_ = random.choice(cls.COORDINATES.keys())
sep1 = cls.get_seps(0)
sep2 = cls.get_seps(0)
return "#" + sep1 + object_ + sep2
@classmethod
def get_coords_data(cls, coords):
"""Format 'coords' as the contents of a coordinates file.
Return a string that contains a line for each astronomical object in
'coords', an iterable argument, listing their right ascensions and
declinations in two columns and, if available, their proper motions
in two additional columns, surrounded by brackets. For example:
269.466450 4.705625 [0.0036] [-.0064]
These columns and brackets are surrounded by a random number (up to the
value of the MAX_SEPS class attribute) or random separators (SEPS class
attribute). The returned string, after written to disk, is expected to
be successfully parsed by load_coorinates().
"""
lines = []
for ra, dec, pm_ra, pm_dec in coords:
sep0 = cls.get_seps(0)
sep1 = cls.get_seps(1)
sep2 = cls.get_seps(0)
line = "%s%.8f%s%.8f%s" % (sep0, ra, sep1, dec, sep2)
if None not in (pm_ra, pm_dec):
sep3 = cls.get_seps(0)
sep4 = cls.get_seps(0)
pm_ra_column = "[%s%.6f%s]" % (sep3, pm_ra, sep4)
sep5 = cls.get_seps(0)
sep6 = cls.get_seps(0)
pm_dec_column = "[%s%.6f%s]" % (sep5, pm_dec, sep6)
sep7 = cls.get_seps(1)
sep8 = cls.get_seps(1)
sep9 = cls.get_seps(0)
line += sep7 + pm_ra_column + sep8 + pm_dec_column + sep9
lines.append(line)
return "\n".join(lines)
def test_load_coordinates(self):
for _ in xrange(NITERS):
# Randomly choose some of the SIMBAD astronomical objects and write
# them to a temporary file, formatting their coordinates and proper
# motions in four columns (or just two, if the proper motions are
# not known) and inserting a random number of separators before,
# between and after the columns and brackets. Then make sure that
# load_coordinates() returns the same astronomical objects, in the
# same order and with the same coordinates that we wrote.
n = random.randint(*self.NCOORDS)
objects = random.sample(self.COORDINATES.values(), n)
data = self.get_coords_data(objects)
with tempinput(data) as path:
coordinates = load_coordinates(path)
for coords, expected in zip(coordinates, objects):
self.assertEqual(coords, expected)
def test_load_coordinates_scientific_notation(self):
# For some datasets that generate coords so close to zero that they end up in scientific notation
data = "7.9720694373e-05 44.6352243008"
with tempinput(data) as path:
coordinates = load_coordinates(path)
coords_list = list(coordinates)
self.assertEqual(len(coords_list), 1)
ra, dec, pm_ra, pm_dec = coords_list[0]
self.assertAlmostEqual(ra, 7.9720694373e-05)
self.assertAlmostEqual(dec, 44.6352243008)
def test_load_coordinates_scientific_notation_with_propper_motion(self):
data = "7.9720694373e-05 44.6352243008 [0.00123] [0.0000432]"
with tempinput(data) as path:
coordinates = load_coordinates(path)
coords_list = list(coordinates)
self.assertEqual(len(coords_list), 1)
ra, dec, pm_ra, pm_dec = coords_list[0]
self.assertAlmostEqual(ra, 7.9720694373e-05)
self.assertAlmostEqual(dec, 44.6352243008)
self.assertAlmostEqual(pm_ra, 0.00123)
self.assertAlmostEqual(pm_dec, 4.32e-05)
def test_load_coordinates_empty_lines_and_comments(self):
# The same as test_load_coordinates(), but randomly inserting a few
# empty and comment lines, as well as inline comments, all of which
# must be ignored by load_coordinates().
for _ in xrange(NITERS):
n = random.randint(*self.NCOORDS)
objects = random.sample(self.COORDINATES.values(), n)
data = self.get_coords_data(objects)
lines = data.split("\n")
# Randomly insert inline comments
for index in range(len(lines)):
if random.random() < self.COMMENT_PROB:
sep = self.get_seps(0)
comment = self.get_comment()
lines[index] += sep + comment
# Randomly insert empty lines
for _ in range(random.randint(*self.NEMPTY)):
index = random.randint(0, len(lines))
empty = self.get_seps(0)
lines.insert(index, empty)
# Randomly insert comment lines
for _ in range(random.randint(*self.NCOMMENTS)):
index = random.randint(0, len(lines))
sep = self.get_seps(0)
comment = self.get_comment()
lines.insert(index, sep + comment)
data = "\n".join(lines)
with tempinput(data) as path:
coordinates = load_coordinates(path)
for coords, expected in zip(coordinates, objects):
self.assertEqual(coords, expected)
def test_load_coordinates_empty_file(self):
# If the file is empty, nothing is returned
with tempinput("") as path:
self.assertEqual([], list(load_coordinates(path)))
def test_load_coordinates_invalid_data(self):
def check_raise(data, exception, regexp):
"""Make sure that load_coordinates() raises 'exception'
when a file containing 'data' is parsed. 'regexp' is the regular
expression that must be matched by the string representation of
the raised exception"""
with tempinput(data) as path:
with self.assertRaisesRegexp(exception, regexp):
list(load_coordinates(path))
def get_coords():
""" Return an element from COORDINATES with known proper motions """
coords = []
for c in self.COORDINATES.itervalues():
if None not in (c.pm_ra, c.pm_dec):
coords.append(c)
return random.choice(coords)
# (1) Lines with other than (a) two floating-point numbers (right
# ascension and declination) or (b) four floating-point numbers (alpha,
# delta and proper motions, the last two surrounded by brackets).
c = get_coords()
unparseable_data = [
# The names of three objects, no coordinates
"\n".join(["NGC 4494", "11 Com b", "TrES-1"]),
# String + float
"foo %.8f" % c.dec,
# Three floating-point numbers
("%.8f " * 3) % c[:3],
# Proper motions not in brackets
("%.8f " * 4) % c,
# Missing declination proper motion
(("%.8f " * 2) + "[%.6f]") % c[:-1],
# Three proper motions
(("%.8f " * 2) + ("[%.6f] " * 3)) % (c + (c.pm_dec, )),
]
regexp = "Unable to parse line"
for data in unparseable_data:
check_raise(data, ValueError, regexp)
# (2) An object with right ascension out of range
c = get_coords()
regexp = "Right ascension .* not in range"
fmt = "%.8f %.8f [%.6f] [%.6f]"
c = c._replace(ra=-24.19933)
data1 = fmt % c # RA < 0
check_raise(data1, ValueError, regexp)
data2 = "%.8f %.8f" % (360, c.dec) # RA >= 360
check_raise(data2, ValueError, regexp)
data3 = "%.8f %.8f" % (417.993, c.dec) # RA >= 360
check_raise(data3, ValueError, regexp)
# (3) An object with declination out of range
c = get_coords()
regexp = "Declination .* not in range"
c = c._replace(dec=-90.21)
data1 = fmt % c # DEC < -90
check_raise(data1, ValueError, regexp)
data2 = "%.8f %.8f" % (c.ra, 113.93) # DEC > +90
check_raise(data2, ValueError, regexp)
def test_get_exact_coordinates(self):
# Barnard's Star (J2000): -798.58 10328.12 (mas/yr)
barnard = Coordinates(269.452075, 4.693391, -0.79858, 10.32812)
# year = epoch, so coordinates do not change
coords = barnard.get_exact_coordinates(2000)
self.assertEqual(coords.ra, barnard.ra)
self.assertEqual(coords.dec, barnard.dec)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 2005 - 2000 = 5 years
# 269.452075 + (-0.79858 * 5) / 3600 = 269.450965861
# 4.693391 + (10.32812 * 5) / 3600 = 4.707735611
coords = barnard.get_exact_coordinates(2005)
self.assertAlmostEqual(coords.ra, 269.450965861)
self.assertAlmostEqual(coords.dec, 4.707735611)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 2014.5 = July 3, 2014
# 2014.5 - 2000 = 14.5 years
# 269.452075 + (-0.79858 * 14.5) / 3600 = 269.448858497
# 4.693391 + (10.32812 * 14.5) / 3600 = 4.734990372
coords = barnard.get_exact_coordinates(2014.5)
self.assertAlmostEqual(coords.ra, 269.448858497)
self.assertAlmostEqual(coords.dec, 4.734990372)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 1975.35 = May 9, 1975
# 1975.35 - 2000 = -24.65 years
# 269.452075 + (-0.79858 * -24.65) / 3600 = 269.457543055
# 4.693391 + (10.32812 * -24.65) / 3600 = 4.622672067
coords = barnard.get_exact_coordinates(1975.35)
self.assertAlmostEqual(coords.ra, 269.457543055)
self.assertAlmostEqual(coords.dec, 4.622672067)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# Kapteyn's Star (J1950): 6505.08 -5730.84 (mas/yr)
kapteyn = Coordinates(77.791453, -44.938748, 6.50508, -5.73084)
# 2008 - 1950 = 58 years
# 77.791453 + ( 6.50508 * 58) / 3600 = 77.896257067
# -44.938748 + (-5.73084 * 58) / 3600 = -45.0310782
coords = kapteyn.get_exact_coordinates(2008, epoch=1950)
self.assertAlmostEqual(coords.ra, 77.896257067)
self.assertAlmostEqual(coords.dec, -45.0310782)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 1905.49180328 = June 30, 1905
# 1905.49180328 - 1950 = -44.50819672
# 77.791453 + ( 6.50508 * -44.50819672) / 3600 = 77.711028172
# -44.938748 + (-5.73084 * -44.50819672) / 3600 = -44.867895402
coords = kapteyn.get_exact_coordinates(1905.49180328, epoch=1950)
self.assertAlmostEqual(coords.ra, 77.711028172)
self.assertAlmostEqual(coords.dec, -44.867895402)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# IOK 1 (z = 6.96, 12.88 Gly)
# No proper motion; object does not move
iok1 = Coordinates(200.999170, 27.415500)
coords = iok1.get_exact_coordinates(2061)
self.assertEqual(coords.ra, iok1.ra)
self.assertEqual(coords.dec, iok1.dec)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
def test_get_exact_coordinates(self):
# Barnard's Star (J2000): -798.58 10328.12 (mas/yr)
barnard = Coordinates(269.452075, 4.693391, -0.79858, 10.32812)
# year = epoch, so coordinates do not change
coords = barnard.get_exact_coordinates(2000)
self.assertEqual(coords.ra, barnard.ra)
self.assertEqual(coords.dec, barnard.dec)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 2005 - 2000 = 5 years
# 269.452075 + (-0.79858 * 5) / 3600 = 269.450965861
# 4.693391 + (10.32812 * 5) / 3600 = 4.707735611
coords = barnard.get_exact_coordinates(2005)
self.assertAlmostEqual(coords.ra, 269.450965861)
self.assertAlmostEqual(coords.dec, 4.707735611)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 2014.5 = July 3, 2014
# 2014.5 - 2000 = 14.5 years
# 269.452075 + (-0.79858 * 14.5) / 3600 = 269.448858497
# 4.693391 + (10.32812 * 14.5) / 3600 = 4.734990372
coords = barnard.get_exact_coordinates(2014.5)
self.assertAlmostEqual(coords.ra, 269.448858497)
self.assertAlmostEqual(coords.dec, 4.734990372)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 1975.35 = May 9, 1975
# 1975.35 - 2000 = -24.65 years
# 269.452075 + (-0.79858 * -24.65) / 3600 = 269.457543055
# 4.693391 + (10.32812 * -24.65) / 3600 = 4.622672067
coords = barnard.get_exact_coordinates(1975.35)
self.assertAlmostEqual(coords.ra, 269.457543055)
self.assertAlmostEqual(coords.dec, 4.622672067)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# Kapteyn's Star (J1950): 6505.08 -5730.84 (mas/yr)
kapteyn = Coordinates(77.791453, -44.938748, 6.50508, -5.73084)
# 2008 - 1950 = 58 years
# 77.791453 + ( 6.50508 * 58) / 3600 = 77.896257067
# -44.938748 + (-5.73084 * 58) / 3600 = -45.0310782
coords = kapteyn.get_exact_coordinates(2008, epoch = 1950)
self.assertAlmostEqual(coords.ra, 77.896257067)
self.assertAlmostEqual(coords.dec, -45.0310782)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# 1905.49180328 = June 30, 1905
# 1905.49180328 - 1950 = -44.50819672
# 77.791453 + ( 6.50508 * -44.50819672) / 3600 = 77.711028172
# -44.938748 + (-5.73084 * -44.50819672) / 3600 = -44.867895402
coords = kapteyn.get_exact_coordinates(1905.49180328, epoch = 1950)
self.assertAlmostEqual(coords.ra, 77.711028172)
self.assertAlmostEqual(coords.dec, -44.867895402)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
# IOK 1 (z = 6.96, 12.88 Gly)
# No proper motion; object does not move
iok1 = Coordinates(200.999170, 27.415500)
coords = iok1.get_exact_coordinates(2061)
self.assertEqual(coords.ra, iok1.ra)
self.assertEqual(coords.dec, iok1.dec)
self.assertIs(coords.pm_ra, None)
self.assertIs(coords.pm_dec, None)
