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A&A 487, 419-429 (2008)
DOI: 10.1051/0004-6361:20079284
Correcting direction-dependent gains in the deconvolution of radio interferometric images
S. Bhatnagar1, T. J. Cornwell2, K. Golap1, and J. M. Uson31 National Radio Astronomy Observatory (Associated Universities Inc. operates the National Radio Astronomy Observatory under cooperative agreement with the National Science Foundation.) , 1003 Lopezville Road, Socorro, NM, 87801, USA
e-mail: [sbhatnag;kgolap]@nrao.edu
2 Australia Telescope National Facility, Epping, New South Wales, Australia, 2120, Australia
e-mail: Tim.Cornwell@csiro.au
3 National Radio Astronomy Observatory, 520 Edgemont Road, Charlottesville, VA, 22903, USA
e-mail: juson@nrao.edu
Received 19 December 2007 / Accepted 3 June 2008
Abstract
Astronomical imaging using aperture synthesis telescopes
requires deconvolution of the point spread function as well as
calibration of instrumental and atmospheric effects. In general,
such effects are time-variable and vary across the field of view as
well, resulting in direction-dependent (DD), time-varying gains.
Most existing imaging and calibration algorithms assume that the
corruptions are direction independent, preventing even moderate
dynamic range full-beam, full-Stokes imaging. We present a general
framework for imaging algorithms which incorporate DD errors. We
describe as well an iterative deconvolution algorithm that corrects
known DD errors due to the antenna power patterns (including
errors due to the antenna polarization response) as well as pointing
errors for high dynamic range full-beam polarimetric imaging. Using
simulations we demonstrate that errors due to realistic primary
beams as well as antenna pointing errors will limit the dynamic
range of upcoming higher sensitivity instruments like the EVLA and
ALMA and that our new algorithm can be used to correct for such
errors. We show that the technique described here corrects for
effects that can be described as approximate unitary operators in
the interferometric measurement equation, such as those due to
antenna pointing errors and non-azimuthally symmetric antenna power
patterns. We have applied this algorithm to VLA 1.4 GHz
observations of a field that contains two "4C" sources and have
obtained Stokes I and V images with systematic errors that are one
order of magnitude lower than those obtained with conventional
imaging tools. Residual systematic errors that are seen at a level
slightly above that of the thermal noise are likely due to selfcalibration instabilities that are triggered by a combination of unknown pointing errors and errors in our assumption of the shape of the primary beam of each antenna. We hope to present a more refined algorithm to deal with the fully general case in due course. Our simulations show that on data with no other calibration errors, the algorithm corrects pointing errors as well as errors due to known
asymmetries in the antenna pattern.
Key words: methods: data analysis -- techniques: interferometic -- techniques: image processing -- techniques: polarimetric
© ESO 2008
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