Marco Schiaffino scite author profile

One of the most challenging aspects of the new-generation Low-Frequency Aperture Array (LFAA) radio telescopes is instrument calibration. The operational LOw-Frequency ARray (LOFAR) instrument and the future LFAA element of the Square Kilometre Array (SKA) require advanced calibration techniques to reach the expected outstanding performance. In this framework, a small array, called Medicina Array Demonstrator (MAD), has been designed and installed in Italy to provide a test bench for antenna characterization and calibration techniques based on a flying artificial test source. A radio-frequency tone is transmitted through a dipole antenna mounted on a micro Unmanned Aerial Vehicle (UAV) (hexacopter) and received by each element of the array. A modern digital FPGA-based back-end is responsible for both data-acquisition and data-reduction. A simple amplitude and phase equalization algorithm is exploited for array calibration owing to the high stability and accuracy of the developed artificial test source. Both the measured embedded element patterns and Exp Astron (2015) 39:405-421 calibrated array patterns are found to be in good agreement with the simulated data. The successful measurement campaign has demonstrated that a UAV-mounted test source provides a means to accurately validate and calibrate the full-polarized response of an antenna/array in operating conditions, including consequently effects like mutual coupling between the array elements and contribution of the environment to the antenna patterns. A similar system can therefore find a future application in the SKA-LFAA context.

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Test-Driven Design of an Active Dual-Polarized Log-Periodic Antenna for the Square Kilometre Array

Bolli

Mezzadrelli

Monari

et al. 2020

IEEE Open J. Antennas Propag.

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An active dual-polarized Log-Periodic antenna has been designed to meet the requirements of the low-frequency (50-350 MHz) radio telescope of the Square Kilometre Array (SKA). The integration of antenna and low noise amplifier has been conceived in order to achieve a high degree of testability. This aspect has been found to be crucial to obtain a smooth frequency response compatible with the SKA science cases. The design has also been driven by other factors such as the large-volume production (more than 130 000 antennas will be built) and the environmental conditions of the harsh Australian desert. A specific verification approach based on both wideband radiometric spectral and spatial measurements in relevant laboratory and in-situ conditions has been developed. Electromagnetic analyses and experimental results exhibit a very good agreement. In December 2019, this antenna was part of the reference solution for the System Critical Design Review of the SKA.

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Design, Modeling, and Test of a System for Atmospheric Electric Field Measurement

Fort

Mugnaini

Vignoli

et al. 2011

IEEE Trans. Instrum. Meas.

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In this paper, a new version of the field-mill sensor\ud structure for atmospheric electric fieldmeasurements is presented.\ud Both the hardware components (i.e., the mechanical structure,\ud the electronic front end, and the acquisition and control systems)\ud and the data processing software are designed in order to reduce\ud power consumption and enhance the instrument metrological performance\ud in terms of accuracy, sensitivity, and frequency band

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Engineering Development Array 2: design, performance, and lessons from an SKA-Low prototype station

Wayth

Sokołowski

Broderick

et al. 2021

J. Astron. Telesc. Instrum. Syst.

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