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systematics_wg_july_19_2017 [2017/07/19 11:03] – bcrill | systematics_wg_july_19_2017 [2017/07/19 11:47] (current) – bcrill | ||
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Agenda/ | Agenda/ | ||
- | on the call: Brendan, Paolo, Colin, Julian, Shaul | + | on the call: Brendan, Paolo, Colin, Julian, Shaul, Maurizio, Joy |
- S4 tools (Colin) | - S4 tools (Colin) | ||
+ | * S4 doesn' | ||
+ | * A generic noise-like systematic (not rolled off by beam) is considered | ||
+ | * Looked at an " | ||
+ | * Also looked at a correlated systematic which can bias cross-spectra, | ||
+ | * Going back to Fischer forecast, including foreground separation in frequency space: can write down what level of systematic corresponds to as a bias in " | ||
+ | * Colin is now applying this to the S4 data challenge. | ||
+ | * Longer term this is meant to provide a benchmark to judge systematics against as a real instrument design takes shape. | ||
+ | * What do we need in order to perform this type of analysis for the CMB probe Imager, given our set of bands and noise levels? | ||
+ | * Can be done just with map noise and frequency bands: though of course it assumes an analysis method | ||
+ | * Also noise shape for a full-sky mission is likely to be quite different. | ||
+ | * Simple parameterization for foreground estimation: probably fine for ~3% sky, but for Probe would use a full-sky template fit. | ||
+ | * Julian points out that there will be a map-based analysis within S4 that will perhaps test this applicability. | ||
- Planck low ell polarization paper [[https:// | - Planck low ell polarization paper [[https:// | ||
* Summary plots | * Summary plots | ||
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* Specific plots | * Specific plots | ||
* Fig 2: noise PSDs and CSDs: correlated cosmic ray hits; Fig A.1 shows this propagated to TT/EE/BB residuals. | * Fig 2: noise PSDs and CSDs: correlated cosmic ray hits; Fig A.1 shows this propagated to TT/EE/BB residuals. | ||
- | * Fig 4: far sidelobe pickup: propagated physical optics models. | + | * Fig 4: HFI far sidelobe pickup: propagated physical optics models. |
* Fig 9: residual ADC nonlinearity with gain correction leaves low ell polarization residuals: see Fig B.13 for what it looks like on the sky | * Fig 9: residual ADC nonlinearity with gain correction leaves low ell polarization residuals: see Fig B.13 for what it looks like on the sky | ||
* Fig 10: " | * Fig 10: " |