The ATA Digital Processing Requirements are Driven by RFI Concerns

TL;DR

This paper discusses how RFI mitigation needs influence the digital processing design of the ATA, emphasizing the importance of high precision and rapid control for effective RFI removal in radio astronomy.

Contribution

It identifies RFI mitigation requirements as the primary driver for digital processing specifications in the ATA, providing a case study relevant to SKA.

Findings

Digital accuracy is driven by RFI mitigation needs.

Beamformer coefficients require 1° precision and millisecond update rate.

RFI signals necessitate high dynamic range and rapid digital control.

Abstract

As a new generation radio telescope, the Allen Telescope Array (ATA) is a prototype for the square kilometer array (SKA). Here we describe recently developed design constraints for the ATA digital signal processing chain as a case study for SKA processing. As radio frequency interference (RFI) becomes increasingly problematical for radio astronomy, radio telescopes must support a wide range of RFI mitigation strategies including online adaptive RFI nulling. We observe that the requirements for digital accuracy and control speed are not driven by astronomical imaging but by RFI. This can be understood from the fact that high dynamic range and digital precision is necessary to remove strong RFI signals from the weak astronomical background, and because RFI signals may change rapidly compared with celestial sources. We review and critique lines of reasoning that lead us to some of the design specifications for ATA digital processing, including these: beamformer coefficients must be specified with at least 1{\deg} precision and at least once per millisecond to enable flexible RFI excision.