Issue |
A&A
Volume 501, Number 3, July III 2009
|
|
---|---|---|
Page(s) | 1185 - 1205 | |
Section | Astronomical instrumentation | |
DOI | https://doi.org/10.1051/0004-6361/200811094 | |
Published online | 29 April 2009 |
Ionospheric calibration of low frequency radio interferometric observations using the peeling scheme
I. Method description and first results
1
Leiden Observatory, Leiden University, PO Box 9513, 2300 RA Leiden, The Netherlands e-mail: intema@strw.leidenuniv.nl
2
Electr. Engineering, Math. and Computer Science, Delft University of Technology, Delft, The Netherlands
3
National Radio Astronomy Observatory, Charlottesville, VA, USA
4
Naval Research Laboratory, Washington DC, USA
Received:
6
October
2008
Accepted:
16
April
2009
Calibration of radio interferometric observations becomes increasingly difficult towards lower frequencies. Below ∼300 MHz, spatially variant refractions and propagation delays of radio waves traveling through the ionosphere cause phase rotations that can vary significantly with time, viewing direction and antenna location. In this article we present a description and first results of SPAM (Source Peeling and Atmospheric Modeling), a new calibration method that attempts to iteratively solve and correct for ionospheric phase errors. To model the ionosphere, we construct a time-variant, 2-dimensional phase screen at fixed height above the Earth's surface. Spatial variations are described by a truncated set of discrete Karhunen-Loève base functions, optimized for an assumed power-law spectral density of free electrons density fluctuations, and a given configuration of calibrator sources and antenna locations. The model is constrained using antenna-based gain phases from individual self-calibrations on the available bright sources in the field-of-view. Application of SPAM on three test cases, a simulated visibility data set and two selected 74 MHz VLA data sets, yields significant improvements in image background noise (5–75 percent reduction) and source peak fluxes (up to 25 percent increase) as compared to the existing self-calibration and field-based calibration methods, which indicates a significant improvement in ionospheric phase calibration accuracy.
Key words: atmospheric effects / methods: numerical / techniques: interferometric
© ESO, 2009
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