http://arxiv.org/abs/1910.12943
We discuss calibration strategies for Phase I of the Hydrogen Epoch of Reionization Array (HERA), which aims to measure the cosmological 21 cm signal from the Epoch of Reionization (EoR). Traditional sky-based gain calibration is difficult for HERA because it is a drift-scan array with a narrower field-of-view compared to other wide-field telescopes. Furthermore, HERA’s redundant sampling of the uv plane and the modest angular resolution of the Phase I instrument make point source modeling and self-calibration techniques difficult to implement with high dynamic range. Nonetheless, we demonstrate a standard methodology for sky-based calibration of HERA using point source catalogues and electromagnetic simulations of the primary beam, and discuss its impact on the 21 cm power spectrum. We also demonstrate a hybrid sky and redundant calibration scheme and compare it to pure sky-based calibration. Our work suggests that the HERA Phase I system can be well-calibrated for a foreground-avoidance power spectrum estimator by applying direction-independent, antenna-based gains with a small set of degrees of freedom across the frequency and time axes. Finally, we show that both sky-based and redundant calibration are currently limited at intermediate k modes by un-modeled diffuse flux and the presence of instrumental coupling systematics, the latter of which we show can contaminate data that were otherwise systematic-free by performing calibration prior to removal.
N. Kern, J. Dillon, A. Parsons, et. al.
Wed, 30 Oct 19
43/77
Comments: Submitted to ApJ