def test_to_waterfall_waterfall():
uvf = UVFlag(test_f_file)
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf.to_waterfall()
uvtest.checkWarnings(uvf.to_waterfall, [], {},
nwarnings=1,
message='This object is already a waterfall')
def test_to_waterfall_bl_flags_or():
uvf = UVFlag(test_f_file)
uvf.to_flag()
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf.to_waterfall(method='or')
nt.assert_true(uvf.type == 'waterfall')
nt.assert_true(uvf.mode == 'flag')
nt.assert_true(uvf.flag_array.shape == (len(uvf.time_array),
len(uvf.freq_array),
len(uvf.polarization_array)))
nt.assert_true(
np.array_equal(uvf.weights_array, np.ones_like(uvf.flag_array,
np.float)))
uvf = UVFlag(test_f_file)
uvf.to_flag()
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf.weights_array[0, 0, 0, 0] = 0.2
uvtest.checkWarnings(uvf.to_waterfall, [], {'method': 'or'},
nwarnings=1,
message='Currently weights are')
nt.assert_true(uvf.type == 'waterfall')
nt.assert_true(uvf.mode == 'flag')
nt.assert_true(uvf.flag_array.shape == (len(uvf.time_array),
len(uvf.freq_array),
len(uvf.polarization_array)))
nt.assert_true(
np.array_equal(uvf.weights_array, np.ones_like(uvf.flag_array,
np.float)))
def test_copy():
uvf = UVFlag(test_f_file)
uvf2 = uvf.copy()
nt.assert_true(uvf == uvf2)
# Make sure it's a copy and not just pointing to same object
uvf.to_waterfall()
nt.assert_false(uvf == uvf2)
def test_to_waterfall_bl():
uvf = UVFlag(test_f_file)
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf.to_waterfall()
nt.assert_true(uvf.type == 'waterfall')
nt.assert_true(uvf.metric_array.shape == (len(uvf.time_array),
len(uvf.freq_array),
len(uvf.polarization_array)))
nt.assert_true(uvf.weights_array.shape == uvf.metric_array.shape)
def test_to_waterfall_ant():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uvf = UVFlag(uvc)
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf.to_waterfall()
nt.assert_true(uvf.type == 'waterfall')
nt.assert_true(uvf.metric_array.shape == (len(uvf.time_array),
len(uvf.freq_array),
len(uvf.polarization_array)))
nt.assert_true(uvf.weights_array.shape == uvf.metric_array.shape)
def test_to_antenna_metric():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uvf = UVFlag(uvc)
uvf.to_waterfall()
uvf.metric_array[0, 10, 0] = 3.2 # Fill in time0, chan10
uvf.metric_array[1, 15, 0] = 2.1 # Fill in time1, chan15
uvf.to_antenna(uvc)
nt.assert_true(np.all(uvf.ant_array == uvc.ant_array))
nt.assert_true(np.all(uvf.time_array == uvc.time_array))
nt.assert_true(np.all(uvf.metric_array[:, 0, 10, 0, 0] == 3.2))
nt.assert_true(np.all(uvf.metric_array[:, 0, 15, 1, 0] == 2.1))
nt.assert_true(
np.isclose(uvf.metric_array.mean(),
(3.2 + 2.1) * uvc.Nants_data / uvf.metric_array.size))
def test_to_antenna_flags():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uvf = UVFlag(uvc)
uvf.to_waterfall()
uvf.to_flag()
uvf.flag_array[0, 10, 0] = True # Flag time0, chan10
uvf.flag_array[1, 15, 0] = True # Flag time1, chan15
uvf.to_antenna(uvc)
nt.assert_true(np.all(uvf.ant_array == uvc.ant_array))
nt.assert_true(np.all(uvf.time_array == uvc.time_array))
nt.assert_true(np.all(uvf.flag_array[:, 0, 10, 0, 0]))
nt.assert_true(np.all(uvf.flag_array[:, 0, 15, 1, 0]))
nt.assert_true(uvf.flag_array.mean() == 2. * uvc.Nants_data /
uvf.flag_array.size)
def test_to_antenna_errors():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uv = UVData()
uv.read_miriad(test_d_file)
uvf = UVFlag(test_f_file)
uvf.to_waterfall()
nt.assert_raises(ValueError, uvf.to_antenna,
7.3) # invalid matching object
uvf = UVFlag(uv)
nt.assert_raises(ValueError, uvf.to_antenna,
uvc) # Cannot pass in baseline type
uvf = UVFlag(test_f_file)
uvf.to_waterfall()
uvf.polarization_array[0] = -4
nt.assert_raises(ValueError, uvf.to_antenna, uvc) # Mismatched pols
def test_to_antenna_metric_force_pol():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uvc.select(jones=-5)
uvf = UVFlag(uvc)
uvf.to_waterfall()
uvf.metric_array[0, 10, 0] = 3.2 # Fill in time0, chan10
uvf.metric_array[1, 15, 0] = 2.1 # Fill in time1, chan15
uvf.polarization_array[0] = -4
uvf.to_antenna(uvc, force_pol=True)
nt.assert_true(np.all(uvf.ant_array == uvc.ant_array))
nt.assert_true(np.all(uvf.time_array == uvc.time_array))
nt.assert_true(np.array_equal(uvf.polarization_array, uvc.jones_array))
nt.assert_true(np.all(uvf.metric_array[:, 0, 10, 0, 0] == 3.2))
nt.assert_true(np.all(uvf.metric_array[:, 0, 15, 1, 0] == 2.1))
nt.assert_true(
np.isclose(uvf.metric_array.mean(),
(3.2 + 2.1) * uvc.Nants_data / uvf.metric_array.size))
def test_to_antenna_force_pol():
uvc = UVCal()
uvc.read_calfits(test_c_file)
uvc.select(jones=-5)
uvf = UVFlag(uvc)
uvf.to_waterfall()
uvf.to_flag()
uvf.flag_array[0, 10, 0] = True # Flag time0, chan10
uvf.flag_array[1, 15, 0] = True # Flag time1, chan15
uvf.polarization_array[0] = -4 # Change pol, but force pol anyway
uvf.to_antenna(uvc, force_pol=True)
nt.assert_true(np.all(uvf.ant_array == uvc.ant_array))
nt.assert_true(np.all(uvf.time_array == uvc.time_array))
nt.assert_true(np.array_equal(uvf.polarization_array, uvc.jones_array))
nt.assert_true(np.all(uvf.flag_array[:, 0, 10, 0, 0]))
nt.assert_true(np.all(uvf.flag_array[:, 0, 15, 1, 0]))
nt.assert_true(uvf.flag_array.mean() == 2 * uvc.Nants_data /
uvf.flag_array.size)
def test_to_baseline_metric():
uv = UVData()
uv.read_miriad(test_d_file)
uvf = UVFlag(uv)
uvf.to_waterfall()
uvf.metric_array[0, 10, 0] = 3.2 # Fill in time0, chan10
uvf.metric_array[1, 15, 0] = 2.1 # Fill in time1, chan15
uvf.to_baseline(uv)
nt.assert_true(np.all(uvf.baseline_array == uv.baseline_array))
nt.assert_true(np.all(uvf.time_array == uv.time_array))
times = np.unique(uvf.time_array)
ind = np.where(uvf.time_array == times[0])[0]
nt0 = len(ind)
nt.assert_true(np.all(uvf.metric_array[ind, 0, 10, 0] == 3.2))
ind = np.where(uvf.time_array == times[1])[0]
nt1 = len(ind)
nt.assert_true(np.all(uvf.metric_array[ind, 0, 15, 0] == 2.1))
nt.assert_true(
np.isclose(uvf.metric_array.mean(),
(3.2 * nt0 + 2.1 * nt1) / uvf.metric_array.size))
def test_to_baseline_flags():
uv = UVData()
uv.read_miriad(test_d_file)
uvf = UVFlag(uv)
uvf.to_waterfall()
uvf.to_flag()
uvf.flag_array[0, 10, 0] = True # Flag time0, chan10
uvf.flag_array[1, 15, 0] = True # Flag time1, chan15
uvf.to_baseline(uv)
nt.assert_true(np.all(uvf.baseline_array == uv.baseline_array))
nt.assert_true(np.all(uvf.time_array == uv.time_array))
times = np.unique(uvf.time_array)
ntrue = 0.0
ind = np.where(uvf.time_array == times[0])[0]
ntrue += len(ind)
nt.assert_true(np.all(uvf.flag_array[ind, 0, 10, 0]))
ind = np.where(uvf.time_array == times[1])[0]
ntrue += len(ind)
nt.assert_true(np.all(uvf.flag_array[ind, 0, 15, 0]))
nt.assert_true(uvf.flag_array.mean() == ntrue / uvf.flag_array.size)
def test_to_baseline_force_pol():
uv = UVData()
uv.read_miriad(test_d_file)
uvf = UVFlag(uv)
uvf.to_waterfall()
uvf.to_flag()
uvf.flag_array[0, 10, 0] = True # Flag time0, chan10
uvf.flag_array[1, 15, 0] = True # Flag time1, chan15
uvf.polarization_array[0] = -4 # Change pol, but force pol anyway
uvf.to_baseline(uv, force_pol=True)
nt.assert_true(np.all(uvf.baseline_array == uv.baseline_array))
nt.assert_true(np.all(uvf.time_array == uv.time_array))
nt.assert_true(
np.array_equal(uvf.polarization_array, uv.polarization_array))
times = np.unique(uvf.time_array)
ntrue = 0.0
ind = np.where(uvf.time_array == times[0])[0]
ntrue += len(ind)
nt.assert_true(np.all(uvf.flag_array[ind, 0, 10, 0]))
ind = np.where(uvf.time_array == times[1])[0]
ntrue += len(ind)
nt.assert_true(np.all(uvf.flag_array[ind, 0, 15, 0]))
nt.assert_true(uvf.flag_array.mean() == ntrue / uvf.flag_array.size)
def test_to_waterfall_bl_multi_pol():
uvf = UVFlag(test_f_file)
uvf.weights_array = np.ones_like(uvf.weights_array)
uvf2 = uvf.copy()
uvf2.polarization_array[0] = -4
uvf.__add__(uvf2, inplace=True,
axis='pol') # Concatenate to form multi-pol object
uvf2 = uvf.copy() # Keep a copy to run with keep_pol=False
uvf.to_waterfall()
nt.assert_true(uvf.type == 'waterfall')
nt.assert_true(uvf.metric_array.shape == (len(uvf.time_array),
len(uvf.freq_array),
len(uvf.polarization_array)))
nt.assert_true(uvf.weights_array.shape == uvf.metric_array.shape)
nt.assert_true(len(uvf.polarization_array) == 2)
# Repeat with keep_pol=False
uvf2.to_waterfall(keep_pol=False)
nt.assert_true(uvf2.type == 'waterfall')
nt.assert_true(uvf2.metric_array.shape == (len(uvf2.time_array),
len(uvf.freq_array), 1))
nt.assert_true(uvf2.weights_array.shape == uvf2.metric_array.shape)
nt.assert_true(len(uvf2.polarization_array) == 1)
nt.assert_true(uvf2.polarization_array[0] == ','.join(
map(str, uvf.polarization_array)))
def test_antpair2ind_nonbaseline():
uvf = UVFlag(test_f_file)
uvf.to_waterfall()
nt.assert_raises(ValueError, uvf.antpair2ind, 0, 3)
def test_uvflag_waterfall_error(self):
uvf = UVFlag(test_f_file)
uvf.to_waterfall()
uvf.to_flag()
nt.assert_raises(ValueError, xrfi.flag_xants, uvf, 0)
