https://github.com/RadioAstronomySoftwareGroup/pyuvdata
Tip revision: 65953f8e68a84a821c75ff1ec8fe3bcc512573fc authored by Nicholas Kern on 24 July 2018, 02:16:45 UTC
check phsae_type == drift in miriad_to_uvfits.py before phasing
check phsae_type == drift in miriad_to_uvfits.py before phasing
Tip revision: 65953f8
test_uvfits.py
# -*- mode: python; coding: utf-8 -*
# Copyright (c) 2018 Radio Astronomy Software Group
# Licensed under the 2-clause BSD License
"""Tests for UVFITS object.
"""
from __future__ import absolute_import, division, print_function
import numpy as np
import copy
import os
import nose.tools as nt
import astropy
from astropy.io import fits
from pyuvdata import UVData
import pyuvdata.utils as uvutils
import pyuvdata.tests as uvtest
from pyuvdata.data import DATA_PATH
def test_ReadNRAO():
"""Test reading in a CASA tutorial uvfits file."""
UV = UVData()
testfile = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
expected_extra_keywords = ['OBSERVER', 'SORTORD', 'SPECSYS',
'RESTFREQ', 'ORIGIN']
uvtest.checkWarnings(UV.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(expected_extra_keywords.sort(),
list(UV.extra_keywords.keys()).sort())
# test reading in header data first, then metadata and then data
UV2 = UVData()
uvtest.checkWarnings(UV2.read, [testfile], {'read_data': False, 'read_metadata': False},
message='Telescope EVLA is not')
nt.assert_equal(expected_extra_keywords.sort(),
list(UV2.extra_keywords.keys()).sort())
nt.assert_raises(ValueError, UV2.check)
UV2.read(testfile, read_data=False)
nt.assert_raises(ValueError, UV2.check)
UV2.read(testfile)
nt.assert_equal(UV, UV2)
# test reading in header & metadata first, then data
UV2 = UVData()
uvtest.checkWarnings(UV2.read, [testfile], {'read_data': False},
message='Telescope EVLA is not')
nt.assert_equal(expected_extra_keywords.sort(),
list(UV2.extra_keywords.keys()).sort())
nt.assert_raises(ValueError, UV2.check)
UV2.read(testfile)
nt.assert_equal(UV, UV2)
# check error trying to read metadata after data is already present
nt.assert_raises(ValueError, uvtest.checkWarnings, UV2.read, [testfile],
{'read_data': False}, message='Telescope EVLA is not')
del(UV)
def test_noSPW():
"""Test reading in a PAPER uvfits file with no spw axis."""
UV = UVData()
testfile_no_spw = os.path.join(DATA_PATH, 'zen.2456865.60537.xy.uvcRREAAM.uvfits')
uvtest.checkWarnings(UV.read, [testfile_no_spw], known_warning='paper_uvfits')
del(UV)
def test_breakReadUVFits():
"""Test errors on reading in a uvfits file with subarrays and other problems."""
UV = UVData()
multi_subarray_file = os.path.join(DATA_PATH, 'multi_subarray.uvfits')
uvtest.checkWarnings(nt.assert_raises, [ValueError, UV.read, multi_subarray_file],
message='Telescope EVLA is not')
del(UV)
def test_spwnotsupported():
"""Test errors on reading in a uvfits file with multiple spws."""
UV = UVData()
testfile = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1scan.uvfits')
nt.assert_raises(ValueError, UV.read, testfile)
del(UV)
def test_readwriteread():
"""
CASA tutorial uvfits loopback test.
Read in uvfits file, write out new uvfits file, read back in and check for
object equality.
"""
uv_in = UVData()
uv_out = UVData()
testfile = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
write_file = os.path.join(DATA_PATH, 'test/outtest_casa.uvfits')
uvtest.checkWarnings(uv_in.read, [testfile], message='Telescope EVLA is not')
uv_in.write_uvfits(write_file)
uvtest.checkWarnings(uv_out.read, [write_file], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
# check that if x_orientation is set, it's read back out properly
uv_in.x_orientation = 'east'
uv_in.write_uvfits(write_file)
uvtest.checkWarnings(uv_out.read, [write_file], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
# check that if antenna_diameters is set, it's read back out properly
uvtest.checkWarnings(uv_in.read, [testfile], message='Telescope EVLA is not')
uv_in.antenna_diameters = np.zeros((uv_in.Nants_telescope,), dtype=np.float) + 14.0
uv_in.write_uvfits(write_file)
uvtest.checkWarnings(uv_out.read, [write_file], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
# check that if antenna_numbers are > 256 everything works
uvtest.checkWarnings(uv_in.read, [testfile], message='Telescope EVLA is not')
uv_in.antenna_numbers = uv_in.antenna_numbers + 256
uv_in.ant_1_array = uv_in.ant_1_array + 256
uv_in.ant_2_array = uv_in.ant_2_array + 256
uv_in.baseline_array = uv_in.antnums_to_baseline(uv_in.ant_1_array, uv_in.ant_2_array)
uvtest.checkWarnings(uv_in.write_uvfits, [write_file],
message='antnums_to_baseline: found > 256 antennas, using 2048 baseline')
uvtest.checkWarnings(uv_out.read, [write_file], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
# check missing telescope_name, timesys vs timsys spelling, xyz_telescope_frame=????
hdu_list = fits.open(write_file)
hdunames = uvutils._fits_indexhdus(hdu_list)
vis_hdu = hdu_list[0]
vis_hdr = vis_hdu.header.copy()
vis_hdr.pop('TELESCOP')
vis_hdu.header = vis_hdr
ant_hdu = hdu_list[hdunames['AIPS AN']]
ant_hdr = ant_hdu.header.copy()
time_sys = ant_hdr.pop('TIMSYS')
ant_hdr['TIMESYS'] = time_sys
ant_hdr['FRAME'] = '????'
ant_hdu.header = ant_hdr
hdulist = fits.HDUList(hdus=[vis_hdu, ant_hdu])
if float(astropy.__version__[0:3]) < 1.3:
hdulist.writeto(write_file, clobber=True)
else:
hdulist.writeto(write_file, overwrite=True)
uvtest.checkWarnings(uv_out.read, [write_file], message='Telescope EVLA is not')
nt.assert_equal(uv_out.telescope_name, 'EVLA')
nt.assert_equal(uv_out.timesys, time_sys)
# check error if timesys is 'IAT'
uvtest.checkWarnings(uv_in.read, [testfile], message='Telescope EVLA is not')
uv_in.timesys = 'IAT'
nt.assert_raises(ValueError, uv_in.write_uvfits, write_file)
uv_in.timesys = 'UTC'
# check error if one time & no inttime specified
uv_singlet = uv_in.select(times=uv_in.time_array[0], inplace=False)
uv_singlet.write_uvfits(write_file)
hdu_list = fits.open(write_file)
hdunames = uvutils._fits_indexhdus(hdu_list)
vis_hdu = hdu_list[0]
vis_hdr = vis_hdu.header.copy()
raw_data_array = vis_hdu.data.data
par_names = np.array(vis_hdu.data.parnames)
pars_use = np.where(par_names != 'INTTIM')[0]
par_names = par_names[pars_use].tolist()
group_parameter_list = [vis_hdu.data.par(name) for name in par_names]
vis_hdu = fits.GroupData(raw_data_array, parnames=par_names,
pardata=group_parameter_list, bitpix=-32)
vis_hdu = fits.GroupsHDU(vis_hdu)
vis_hdu.header = vis_hdr
ant_hdu = hdu_list[hdunames['AIPS AN']]
hdulist = fits.HDUList(hdus=[vis_hdu, ant_hdu])
if float(astropy.__version__[0:3]) < 1.3:
hdulist.writeto(write_file, clobber=True)
else:
hdulist.writeto(write_file, overwrite=True)
uvtest.checkWarnings(nt.assert_raises, [ValueError, uv_out.read, write_file],
message=['Telescope EVLA is not',
'ERFA function "utcut1" yielded 1 of "dubious year (Note 3)"',
'ERFA function "utctai" yielded 1 of "dubious year (Note 3)"'],
nwarnings=3, category=[UserWarning, astropy._erfa.core.ErfaWarning,
astropy._erfa.core.ErfaWarning])
# check that unflagged data with nsample = 0 will cause warnings
uv_in.nsample_array[list(range(11, 22))] = 0
uv_in.flag_array[list(range(11, 22))] = False
uvtest.checkWarnings(uv_in.write_uvfits, [write_file], message='Some unflagged data has nsample = 0')
del(uv_in)
del(uv_out)
def test_extra_keywords():
uv_in = UVData()
uv_out = UVData()
uvfits_file = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
testfile = os.path.join(DATA_PATH, 'test/outtest_casa.uvfits')
uvtest.checkWarnings(uv_in.read, [uvfits_file], message='Telescope EVLA is not')
# check for warnings & errors with extra_keywords that are dicts, lists or arrays
uv_in.extra_keywords['testdict'] = {'testkey': 23}
uvtest.checkWarnings(uv_in.check, message=['testdict in extra_keywords is a '
'list, array or dict'])
nt.assert_raises(TypeError, uv_in.write_uvfits, testfile, run_check=False)
uv_in.extra_keywords.pop('testdict')
uv_in.extra_keywords['testlist'] = [12, 14, 90]
uvtest.checkWarnings(uv_in.check, message=['testlist in extra_keywords is a '
'list, array or dict'])
nt.assert_raises(TypeError, uv_in.write_uvfits, testfile, run_check=False)
uv_in.extra_keywords.pop('testlist')
uv_in.extra_keywords['testarr'] = np.array([12, 14, 90])
uvtest.checkWarnings(uv_in.check, message=['testarr in extra_keywords is a '
'list, array or dict'])
nt.assert_raises(TypeError, uv_in.write_uvfits, testfile, run_check=False)
uv_in.extra_keywords.pop('testarr')
# check for warnings with extra_keywords keys that are too long
uv_in.extra_keywords['test_long_key'] = True
uvtest.checkWarnings(uv_in.check, message=['key test_long_key in extra_keywords '
'is longer than 8 characters'])
uvtest.checkWarnings(uv_in.write_uvfits, [testfile], {'run_check': False},
message=['key test_long_key in extra_keywords is longer than 8 characters'])
uv_in.extra_keywords.pop('test_long_key')
# check handling of boolean keywords
uv_in.extra_keywords['bool'] = True
uv_in.extra_keywords['bool2'] = False
uv_in.write_uvfits(testfile)
uvtest.checkWarnings(uv_out.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
uv_in.extra_keywords.pop('bool')
uv_in.extra_keywords.pop('bool2')
# check handling of int-like keywords
uv_in.extra_keywords['int1'] = np.int(5)
uv_in.extra_keywords['int2'] = 7
uv_in.write_uvfits(testfile)
uvtest.checkWarnings(uv_out.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
uv_in.extra_keywords.pop('int1')
uv_in.extra_keywords.pop('int2')
# check handling of float-like keywords
uv_in.extra_keywords['float1'] = np.int64(5.3)
uv_in.extra_keywords['float2'] = 6.9
uv_in.write_uvfits(testfile)
uvtest.checkWarnings(uv_out.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
uv_in.extra_keywords.pop('float1')
uv_in.extra_keywords.pop('float2')
# check handling of complex-like keywords
uv_in.extra_keywords['complex1'] = np.complex64(5.3 + 1.2j)
uv_in.extra_keywords['complex2'] = 6.9 + 4.6j
uv_in.write_uvfits(testfile)
uvtest.checkWarnings(uv_out.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
uv_in.extra_keywords.pop('complex1')
uv_in.extra_keywords.pop('complex2')
# check handling of comment keywords
uv_in.extra_keywords['comment'] = ('this is a very long comment that will '
'be broken into several lines\nif '
'everything works properly.')
uv_in.write_uvfits(testfile)
uvtest.checkWarnings(uv_out.read, [testfile], message='Telescope EVLA is not')
nt.assert_equal(uv_in, uv_out)
def test_select_read():
uvfits_uv = UVData()
uvfits_uv2 = UVData()
uvfits_file = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
# select on antennas
ants_to_keep = np.array([0, 19, 11, 24, 3, 23, 1, 20, 21])
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'antenna_nums': ants_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(antenna_nums=ants_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# select on frequency channels
chans_to_keep = np.arange(12, 22)
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'freq_chans': chans_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(freq_chans=chans_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# check writing & reading single frequency files
uvfits_uv.select(freq_chans=[0])
testfile = os.path.join(DATA_PATH, 'test/outtest_casa.uvfits')
uvfits_uv.write_uvfits(testfile)
uvtest.checkWarnings(uvfits_uv2.read, [testfile],
message='Telescope EVLA is not')
nt.assert_equal(uvfits_uv, uvfits_uv2)
# select on pols
pols_to_keep = [-1, -2]
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'polarizations': pols_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(polarizations=pols_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# select on read using time_range
unique_times = np.unique(uvfits_uv.time_array)
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'time_range': [unique_times[0], unique_times[1]]},
nwarnings=2,
message=['Warning: "time_range" keyword is set',
'Telescope EVLA is not'])
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(times=unique_times[0:2])
nt.assert_equal(uvfits_uv, uvfits_uv2)
# now test selecting on multiple axes
# frequencies first
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'antenna_nums': ants_to_keep,
'freq_chans': chans_to_keep,
'polarizations': pols_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(antenna_nums=ants_to_keep, freq_chans=chans_to_keep,
polarizations=pols_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# baselines first
ants_to_keep = np.array([0, 1])
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'antenna_nums': ants_to_keep,
'freq_chans': chans_to_keep,
'polarizations': pols_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(antenna_nums=ants_to_keep, freq_chans=chans_to_keep,
polarizations=pols_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# polarizations first
ants_to_keep = np.array([0, 1, 2, 3, 6, 7, 8, 11, 14, 18, 19, 20, 21, 22])
chans_to_keep = np.arange(12, 64)
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file],
{'antenna_nums': ants_to_keep,
'freq_chans': chans_to_keep,
'polarizations': pols_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [uvfits_file],
message='Telescope EVLA is not')
uvfits_uv2.select(antenna_nums=ants_to_keep, freq_chans=chans_to_keep,
polarizations=pols_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# repeat with no spw file
uvfitsfile_no_spw = os.path.join(DATA_PATH, 'zen.2456865.60537.xy.uvcRREAAM.uvfits')
# select on antennas
ants_to_keep = np.array([2, 4, 5])
uvtest.checkWarnings(uvfits_uv.read, [uvfitsfile_no_spw],
{'antenna_nums': ants_to_keep},
known_warning='paper_uvfits')
uvtest.checkWarnings(uvfits_uv2.read, [uvfitsfile_no_spw],
known_warning='paper_uvfits')
uvfits_uv2.select(antenna_nums=ants_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# select on frequency channels
chans_to_keep = np.arange(4, 8)
uvtest.checkWarnings(uvfits_uv.read, [uvfitsfile_no_spw],
{'freq_chans': chans_to_keep},
known_warning='paper_uvfits')
uvtest.checkWarnings(uvfits_uv2.read, [uvfitsfile_no_spw],
known_warning='paper_uvfits')
uvfits_uv2.select(freq_chans=chans_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
# select on pols
# this requires writing a new file because the no spw file we have has only 1 pol
hdu_list = fits.open(uvfits_file)
hdunames = uvutils._fits_indexhdus(hdu_list)
vis_hdu = hdu_list[0]
vis_hdr = vis_hdu.header.copy()
raw_data_array = vis_hdu.data.data
raw_data_array = raw_data_array[:, :, :, 0, :, :, :]
vis_hdr['NAXIS'] = 6
vis_hdr['NAXIS5'] = vis_hdr['NAXIS6']
vis_hdr['CTYPE5'] = vis_hdr['CTYPE6']
vis_hdr['CRVAL5'] = vis_hdr['CRVAL6']
vis_hdr['CDELT5'] = vis_hdr['CDELT6']
vis_hdr['CRPIX5'] = vis_hdr['CRPIX6']
vis_hdr['CROTA5'] = vis_hdr['CROTA6']
vis_hdr['NAXIS6'] = vis_hdr['NAXIS7']
vis_hdr['CTYPE6'] = vis_hdr['CTYPE7']
vis_hdr['CRVAL6'] = vis_hdr['CRVAL7']
vis_hdr['CDELT6'] = vis_hdr['CDELT7']
vis_hdr['CRPIX6'] = vis_hdr['CRPIX7']
vis_hdr['CROTA6'] = vis_hdr['CROTA7']
vis_hdr.pop('NAXIS7')
vis_hdr.pop('CTYPE7')
vis_hdr.pop('CRVAL7')
vis_hdr.pop('CDELT7')
vis_hdr.pop('CRPIX7')
vis_hdr.pop('CROTA7')
par_names = vis_hdu.data.parnames
group_parameter_list = [vis_hdu.data.par(ind) for
ind in range(len(par_names))]
vis_hdu = fits.GroupData(raw_data_array, parnames=par_names,
pardata=group_parameter_list, bitpix=-32)
vis_hdu = fits.GroupsHDU(vis_hdu)
vis_hdu.header = vis_hdr
ant_hdu = hdu_list[hdunames['AIPS AN']]
write_file = os.path.join(DATA_PATH, 'test/outtest_casa.uvfits')
hdulist = fits.HDUList(hdus=[vis_hdu, ant_hdu])
if float(astropy.__version__[0:3]) < 1.3:
hdulist.writeto(write_file, clobber=True)
else:
hdulist.writeto(write_file, overwrite=True)
pols_to_keep = [-1, -2]
uvtest.checkWarnings(uvfits_uv.read, [write_file],
{'polarizations': pols_to_keep},
message='Telescope EVLA is not')
uvtest.checkWarnings(uvfits_uv2.read, [write_file],
message='Telescope EVLA is not')
uvfits_uv2.select(polarizations=pols_to_keep)
nt.assert_equal(uvfits_uv, uvfits_uv2)
def test_ReadUVFitsWriteMiriad():
"""
read uvfits, write miriad test.
Read in uvfits file, write out as miriad, read back in and check for
object equality.
"""
uvfits_uv = UVData()
miriad_uv = UVData()
uvfits_file = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
testfile = os.path.join(DATA_PATH, 'test/outtest_miriad')
uvtest.checkWarnings(uvfits_uv.read, [uvfits_file], message='Telescope EVLA is not')
uvfits_uv.write_miriad(testfile, clobber=True)
uvtest.checkWarnings(miriad_uv.read_miriad, [testfile], message='Telescope EVLA is not')
nt.assert_equal(miriad_uv, uvfits_uv)
# check that setting the phase_type keyword also works
uvtest.checkWarnings(miriad_uv.read_miriad, [testfile], {'phase_type': 'phased'},
message='Telescope EVLA is not')
# check that setting the phase_type to drift raises an error
nt.assert_raises(ValueError, miriad_uv.read_miriad, testfile, phase_type='drift'),
# check that setting it works after selecting a single time
uvfits_uv.select(times=uvfits_uv.time_array[0])
uvfits_uv.write_miriad(testfile, clobber=True)
uvtest.checkWarnings(miriad_uv.read_miriad, [testfile],
message='Telescope EVLA is not')
nt.assert_equal(miriad_uv, uvfits_uv)
del(uvfits_uv)
del(miriad_uv)
def test_multi_files():
"""
Reading multiple files at once.
"""
uv_full = UVData()
uvfits_file = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.uvfits')
testfile1 = os.path.join(DATA_PATH, 'test/uv1.uvfits')
testfile2 = os.path.join(DATA_PATH, 'test/uv2.uvfits')
uvtest.checkWarnings(uv_full.read, [uvfits_file], message='Telescope EVLA is not')
uv1 = copy.deepcopy(uv_full)
uv2 = copy.deepcopy(uv_full)
uv1.select(freq_chans=np.arange(0, 32))
uv2.select(freq_chans=np.arange(32, 64))
uv1.write_uvfits(testfile1)
uv2.write_uvfits(testfile2)
uvtest.checkWarnings(uv1.read, [[testfile1, testfile2]], nwarnings=2,
message=['Telescope EVLA is not'])
# Check history is correct, before replacing and doing a full object check
nt.assert_true(uvutils._check_histories(uv_full.history + ' Downselected to '
'specific frequencies using pyuvdata. '
'Combined data along frequency axis '
'using pyuvdata.', uv1.history))
uv1.history = uv_full.history
nt.assert_equal(uv1, uv_full)
# check raises error if read_data and read_metadata are False
nt.assert_raises(ValueError, uv1.read, [testfile1, testfile2],
read_data=False, read_metadata=False)
# check raises error if read_data is False and read_metadata is True
nt.assert_raises(ValueError, uv1.read, [testfile1, testfile2],
read_data=False, read_metadata=True)
# check raises error if only reading data on a list of files
uv1 = UVData()
uvtest.checkWarnings(uv1.read, [uvfits_file], {'read_data': False},
message=['Telescope EVLA is not'])
nt.assert_raises(ValueError, uv1.read, [testfile1, testfile2])
def test_readMSWriteUVFits_CASAHistory():
"""
read in .ms file.
Write to a uvfits file, read back in and check for casa_history parameter
"""
ms_uv = UVData()
uvfits_uv = UVData()
ms_file = os.path.join(DATA_PATH, 'day2_TDEM0003_10s_norx_1src_1spw.ms')
testfile = os.path.join(DATA_PATH, 'test/outtest.uvfits')
ms_uv.read_ms(ms_file)
ms_uv.write_uvfits(testfile, spoof_nonessential=True)
uvtest.checkWarnings(uvfits_uv.read, [testfile],
message='Telescope EVLA is not')
nt.assert_equal(ms_uv, uvfits_uv)
del(uvfits_uv)
del(ms_uv)