def setUp(self):
self.dir = './test_results'
os.makedirs(self.dir, exist_ok=True)
self.niter = 1000
self.lowcore = create_named_configuration('LOWBD2-CORE')
self.nchan = 5
self.times = (numpy.pi / 12.0) * numpy.linspace(-3.0, 3.0, 7)
self.frequency = numpy.linspace(0.9e8, 1.1e8, self.nchan)
self.channel_bandwidth = numpy.array(self.nchan * [self.frequency[1] - self.frequency[0]])
self.phasecentre = SkyCoord(ra=+0.0 * u.deg, dec=-45.0 * u.deg, frame='icrs', equinox='J2000')
self.vis = create_visibility(self.lowcore, self.times, self.frequency, self.channel_bandwidth,
phasecentre=self.phasecentre, weight=1.0,
polarisation_frame=PolarisationFrame('stokesI'))
self.vis.data['vis'] *= 0.0
# Create model
self.test_model = create_low_test_image_from_gleam(npixel=512, cellsize=0.001,
phasecentre=self.vis.phasecentre,
frequency=self.frequency,
channel_bandwidth=self.channel_bandwidth)
beam = create_low_test_beam(self.test_model)
export_image_to_fits(beam, "%s/test_deconvolve_msmfsclean_beam.fits" % self.dir)
self.test_model.data *= beam.data
export_image_to_fits(self.test_model, "%s/test_deconvolve_msmfsclean_model.fits" % self.dir)
self.vis = predict_2d(self.vis, self.test_model)
assert numpy.max(numpy.abs(self.vis.vis)) > 0.0
self.model = create_image_from_visibility(self.vis, npixel=512, cellsize=0.001,
polarisation_frame=PolarisationFrame('stokesI'))
self.dirty, sumwt = invert_2d(self.vis, self.model)
self.psf, sumwt = invert_2d(self.vis, self.model, dopsf=True)
export_image_to_fits(self.dirty, "%s/test_deconvolve_msmfsclean_dirty.fits" % self.dir)
export_image_to_fits(self.psf, "%s/test_deconvolve_msmfsclean_psf.fits" % self.dir)
window = numpy.ones(shape=self.model.shape, dtype=numpy.bool)
window[..., 129:384, 129:384] = True
self.innerquarter = create_image_from_array(window, self.model.wcs)
def actualSetUp(self,
time=None,
frequency=None,
dospectral=False,
dopol=False):
self.lowcore = create_named_configuration('LOWBD2-CORE')
self.times = (numpy.pi / 12.0) * numpy.linspace(-3.0, 3.0, 5)
if time is not None:
self.times = time
log.info("Times are %s" % (self.times))
if dospectral:
self.nchan = 3
self.frequency = numpy.array([0.9e8, 1e8, 1.1e8])
self.channel_bandwidth = numpy.array([1e7, 1e7, 1e7])
else:
self.frequency = numpy.array([1e8])
self.channel_bandwidth = numpy.array([1e7])
if dopol:
self.vis_pol = PolarisationFrame('linear')
self.image_pol = PolarisationFrame('stokesIQUV')
else:
self.vis_pol = PolarisationFrame('stokesI')
self.image_pol = PolarisationFrame('stokesI')
if dopol:
f = numpy.array([100.0, 20.0, -10.0, 1.0])
else:
f = numpy.array([100.0])
if dospectral:
numpy.array([f, 0.8 * f, 0.6 * f])
else:
numpy.array([f])
self.phasecentre = SkyCoord(ra=+180.0 * u.deg,
dec=-60.0 * u.deg,
frame='icrs',
equinox='J2000')
self.componentvis = create_visibility(
self.lowcore,
self.times,
self.frequency,
channel_bandwidth=self.channel_bandwidth,
phasecentre=self.phasecentre,
weight=1.0,
polarisation_frame=self.vis_pol)
self.uvw = self.componentvis.data['uvw']
self.componentvis.data['vis'] *= 0.0
# Create model
self.model = create_image_from_visibility(
self.componentvis,
npixel=512,
cellsize=0.001,
nchan=len(self.frequency),
polarisation_frame=self.image_pol)
def create_empty_handle(vis_graph_list, npixel, cellsize, frequency,
channel_bandwidth, polarisation_frame):
return vis_graph_list.map(
lambda vis: (vis[0],
create_image_from_visibility(
vis[1],
npixel=npixel,
cellsize=cellsize,
frequency=[frequency[vis[0][2]]],
channel_bandwidth=[channel_bandwidth[vis[0][2]]],
polarisation_frame=PolarisationFrame("stokesI"))))
def setUp(self):
self.dir = './test_results'
os.makedirs(self.dir, exist_ok=True)
self.lowcore = create_named_configuration('LOWBD2-CORE')
self.times = (numpy.pi / (12.0)) * numpy.linspace(-3.0, 3.0, 7)
self.frequency = numpy.array([1e8])
self.channel_bandwidth = numpy.array([1e6])
self.phasecentre = SkyCoord(ra=+180.0 * u.deg,
dec=-60.0 * u.deg,
frame='icrs',
equinox='J2000')
self.vis = create_visibility(
self.lowcore,
self.times,
self.frequency,
channel_bandwidth=self.channel_bandwidth,
phasecentre=self.phasecentre,
weight=1.0,
polarisation_frame=PolarisationFrame('stokesI'))
self.vis.data['vis'] *= 0.0
# Create model
self.test_model = create_test_image(cellsize=0.001,
phasecentre=self.vis.phasecentre,
frequency=self.frequency)
self.vis = predict_2d(self.vis, self.test_model)
assert numpy.max(numpy.abs(self.vis.vis)) > 0.0
self.model = create_image_from_visibility(
self.vis,
npixel=512,
cellsize=0.001,
polarisation_frame=PolarisationFrame('stokesI'))
self.dirty, sumwt = invert_2d(self.vis, self.model)
self.psf, sumwt = invert_2d(self.vis, self.model, dopsf=True)
window = numpy.zeros(shape=self.model.shape, dtype=numpy.bool)
window[..., 129:384, 129:384] = True
self.innerquarter = create_image_from_array(
window,
self.model.wcs,
polarisation_frame=PolarisationFrame('stokesI'))
def test_create_primary_beams_vla(self):
self.createVis(config='LOWBD2', rmax=1000.0)
model = create_image_from_visibility(self.vis, cellsize=0.00001, override_cellsize=True)
beam=create_pb_vla(model)
assert numpy.max(beam.data) > 0.0
export_image_to_fits(beam, "%s/primary_beam_vla.fits" % self.dir)