Calibration Schemes with O(NN) Scaling for Large-N Radio Interferometers Built on a Regular Grid

Abstract

Future generations of radio interferometers targeting the 21\,cm signal at cosmological distances with N 1000 antennas could face a significant computational challenge in building correlators with the traditional architecture, whose computational resource requirement scales as O(N2) with array size. The fundamental output of such correlators is the cross-correlation products of all antenna pairs in the array. The FFT-correlator architecture reduces the computational resources scaling to O(NN) by computing cross-correlation products through a spatial Fourier transform. However, the output of the FFT-correlator is meaningful only when the input antenna voltages are gain- and phase-calibrated. Traditionally, interferometric calibration has used the O(N2) cross-correlations produced by a standard correlator. This paper proposes two real-time calibration schemes that could work in parallel with an FFT-correlator as a self-contained O(NN) correlator system that can be scaled to large-N redundant arrays. We compare the performance and scalability of these two calibration schemes and find that they result in antenna gains whose variance decreases as 1/N with increase in the size of the array.