The Electromagnetic Characteristics of the Tianlai Cylindrical Pathfinder Array

TL;DR

This paper presents electromagnetic simulations of the Tianlai cylindrical array, analyzing its response, mutual coupling, and noise characteristics to aid 21cm intensity mapping signal extraction.

Contribution

It introduces a practical simulation approach combining multiple methods to model the array's electromagnetic response and compares results with observations, providing insights into instrument effects.

Findings

Simulation accurately reproduces observed features.

Mutual coupling decreases with feed distance.

Simulated noise estimates agree with data.

Abstract

A great challenge for 21 cm intensity mapping experiments is the strong foreground radiation which is orders of magnitude brighter than the 21cm signal. Removal of the foreground takes advantage of the fact that its frequency spectrum is smooth while the redshifted 21cm signal spectrum is stochastic. However, a complication is the non-smoothness of the instrument response. This paper describes the electromagnetic simulation of the Tianlai cylinder array, a pathfinder for 21 cm intensity mapping experiments. Due to the vast scales involved, a direct simulation requires large amount of computing resources. We have made the simulation practical by using a combination of methods: first simulate a single feed, then an array of feed units, finally with the feed array and a cylindrical reflector together, to obtain the response for a single cylinder. We studied its radiation pattern, bandpass response and the effects of mutual coupling between feed units, and compared the results with observation. Many features seen in the measurement result are well reproduced in the simulation, especially the oscillatory features which are associated with the standing waves on the reflector. The mutual coupling between feed units is quantified with S-parameters, which decrease as the distance between the two feeds increases. Based on the simulated S-parameters, we estimate the correlated noise which has been seen in the visibility data, the results show very good agreement with the data in both magnitude and frequency structures. These results provide useful insights on the problem of 21cm signal extraction for real instruments.