📝 SummarXiv

Abstract

We introduce N+2 mapmaking as a novel approach to constructing maps in both intensity and polarization for multi-detector CMB data. The motivation behind this method is two-fold: Firstly, it provides individual temperature detector maps from a multi-detector set, which may be useful for component separation purposes, in particular for line emission reconstruction. Secondly, it simultaneously outputs coadded polarization maps with minimal temperature-to-polarization leakage sensitivity. Algorithmically speaking, the N+2 mapmaker is closely related to the `spurious mapmaking' algorithm pioneered by the WMAP team, but rather than solving for a spurious S map together with the three normal Stokes IQU parameters, we solve for N temperature maps and two Stokes (Q and U) parameters per pixel. The result is a statistically coherent set of physically meaningful per-detector temperature maps, each with slightly different bandpasses as defined by each detector, combined with coadded polarization maps. We test this approach on Planck Low Frequency Instrument (LFI) 30 GHz data, and find that the Planck scanning strategy is too poorly cross-linked to allow for a clean separation between temperature and polarization. However, noting that pairs of detectors within a single horn are strongly anti-correlated, we anticipate that solving for horn maps, as opposed to individual detector maps, may provide an optimal compromise between noise and temperature-to-polarization leakage minimization. When applied to simulated data with a rotating half-wave plate, for which the polarization angle coverage is greatly improved, the algorithm performs as expected.