Drone Beam Mapping of the TONE Radio Dish Array

Drone Beam Mapping of the TONE Radio Dish Array

Drone-based beam measurements are a promising avenue to tackle the critical challenge of calibration for 21 cm cosmology telescopes. In this paper, we introduce a new drone-based calibration system for 400–800 MHz radio observatories, describing its instrumentation and first deployment. We discuss m...

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Bibliographic Details
Main Authors: Emily R. Kuhn, Will Tyndall, Benjamin R. B. Saliwanchik, Anna Rose Polish, Maile Harris, Laura B. Newburgh
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astronomical Journal
Subjects:
Radio astronomy
Calibration
Radio interferometers
Online Access:https://doi.org/10.3847/1538-3881/add269
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Summary:Drone-based beam measurements are a promising avenue to tackle the critical challenge of calibration for 21 cm cosmology telescopes. In this paper, we introduce a new drone-based calibration system for 400–800 MHz radio observatories, describing its instrumentation and first deployment. We discuss measurements of the TONE array, a CHIME/FRB outrigger pathfinder, and present results, including full 2D high spatial resolution beam maps in both co- and cross-polarization, as well as comparisons to simulations. The polarized beam maps cover a 70 ^∘  × 70 ^∘ grid, capturing the first two sidelobes and measuring the TONE main beam and first sidelobe with 7%–9% statistical errors. We investigate polarization angle alignment with frequency, finding significant polarization leakage in the TONE antennas at frequencies above 600 MHz, and a polarization axis rotation with frequency. We describe statistical and systematic errors, as well as measurements of radio frequency interference (RFI) from the drone and equipment. Our drone system is the first to incorporate a broadband switched calibration source in the drone payload, enabling background subtraction and direct measurements of the RFI emitted by the drone. The results presented are the first drone-based 2D measurements of cross-polar beam structure and of polarization alignment of an array. The high frequency and spatial resolution achieved with this system have revealed the rich structure of the beam of each antenna, and enabled comparisons between individual dishes and to electromagnetic simulations.
ISSN:1538-3881

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