Sidelobe Modification for Reflector Antennas by Electronically Reconfigurable Rim Scattering

Dynamic modification of the pattern of a reflector antenna system traditionally requires an array of feeds. This letter presents an alternative approach in which the scattering from a fraction of the reflector around the rim is passively modified using, for example, an electronically reconfigurable reflectarray. This facilitates flexible sidelobe modification, including sidelobe canceling, for systems employing a single feed. Applications for such a system include radio astronomy, where deleterious levels of interference from satellites enter through sidelobes. We show that an efficient reconfigurable surface occupying about 11% of the area of an axisymmetric circular paraboloidal reflector antenna fed from the prime focus is sufficient to null interference arriving from any direction outside the main lobe with little change in the main lobe characteristics. We further show that the required surface area is independent of frequency and that the same performance can be obtained using 1 b phase control of the constituent unit cells for a reconfigurable surface occupying an additional 6% of the reflector surface.

[1]  Steven W. Ellingson,et al.  Path Loss in Reconfigurable Intelligent Surface-Enabled Channels , 2019, 2021 IEEE 32nd Annual International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC).

[2]  R.C. Johnson,et al.  Introduction to adaptive arrays , 1982, Proceedings of the IEEE.

[3]  G. Massa,et al.  Control of reflector antennas performance by rim loading , 1981 .

[4]  Sean Victor Hum,et al.  Reconfigurable Reflectarrays and Array Lenses for Dynamic Antenna Beam Control: A Review , 2013, IEEE Transactions on Antennas and Propagation.

[5]  Robert J. Selina,et al.  The Next-Generation Very Large Array: a technical overview , 2018, Astronomical Telescopes + Instrumentation.

[6]  S. Ellingson Antennas in Radio Telescope Systems , 2015 .

[7]  Bryan Butler,et al.  The Expanded Very Large Array , 2009, Proceedings of the IEEE.

[8]  H. Chou,et al.  Flexible Dual-Band Dual-Beam Radiation of Reflector Antennas by Embedding Resonant Phase Alignment Elements for Power Refocusing , 2020, IEEE Transactions on Antennas and Propagation.

[9]  Trevor S. Bird Fundamentals of Aperture Antennas and Arrays: From Theory to Design, Fabrication and Testing , 2016 .

[10]  E. Phinney,et al.  The DSA-2000 -- A Radio Survey Camera , 2019, 1907.07648.

[11]  Emil Björnson,et al.  Intelligent Reflecting Surfaces: Physics, Propagation, and Pathloss Modeling , 2019, IEEE Wireless Communications Letters.

[12]  Todd R. Hunter,et al.  The Green Bank Telescope , 2009, Proceedings of the IEEE.

[13]  H. Chou,et al.  Local Area Radiation Sidelobe Suppression of Reflector Antennas by Embedding Periodic Metallic Elements Along the Edge Boundary , 2017, IEEE Transactions on Antennas and Propagation.

[14]  Erdem Yazgan,et al.  Pattern optimization of a reflector antenna with planar-array feeds and cluster feeds , 1997 .