Difference between revisions of "Beam Window Functions"
| Line 12: | Line 12: | ||
They are available in two forms: | They are available in two forms: | ||
==== Beam window functions ==== | ==== Beam window functions ==== | ||
| − | <math>b_{T}, b_{E}, b_{B},</math> | + | <math>b_{T}, b_{E}, b_{B},</math> such that <br /> |
| − | such that | + | <math>C_{XX}^{map}(\ell) = b_{X}^2(\ell) w_{pix}^2(\ell) C_{XX}^{sky}(\ell)</math> <br /> |
| − | <math>C_{XX}^{map}(\ell) = b_{X}^2(\ell) w_{pix}^2(\ell) C_{XX}^{sky}(\ell)</math> | ||
for X=T, E or B, and where <math>w_{pix}</math> is the pixel window function, which depends on the resolution parameter Nside (=2048 for Planck HFI maps). | for X=T, E or B, and where <math>w_{pix}</math> is the pixel window function, which depends on the resolution parameter Nside (=2048 for Planck HFI maps). | ||
| Line 21: | Line 20: | ||
==== Beam matrices ==== | ==== Beam matrices ==== | ||
| − | <math>W_{XY,X'Y'}(\ell)</math>, | + | <math>W_{XY,X'Y'}(\ell)</math>, such that <br /> |
| − | such that | + | <math>C_{XY}^{map}(\ell) = \sum_{X',Y'} W_{XY,X'Y'}(\ell) w_{pix}^2(\ell) C_{X'Y'}^{sky}(\ell)</math> <br /> |
| − | <math>C_{XY}^{map}(\ell) = \sum_{X',Y'} W_{XY,X'Y'}(\ell) w_{pix}^2(\ell) C_{X'Y'}^{sky}(\ell)</math> | ||
for X,Y,X',Y'= T, E or B. | for X,Y,X',Y'= T, E or B. | ||
They are provided in FITS files, containing 4 extensions each: | They are provided in FITS files, containing 4 extensions each: | ||
| − | # first one, named 'TT', contains the 9 fields: 'TT_2_TT', 'TT_2_EE', 'TT_2_BB', 'TT_2_TE', 'TT_2_TB', 'TT_2_EB', 'TT_2_ET', 'TT_2_BT', 'TT_2_BE' | + | # first one, named 'TT', contains the 9 fields: 'TT_2_TT', 'TT_2_EE', 'TT_2_BB', 'TT_2_TE', 'TT_2_TB', 'TT_2_EB', 'TT_2_ET', 'TT_2_BT', 'TT_2_BE'<br /> |
| − | describing the ℓ-dependent leakage template of TT towards TT, EE, BB, ... respectively. | + | describing the ℓ-dependent leakage template of TT towards TT, EE, BB, ... respectively.<br /> |
TT_2_TT is the usual W'_TT_'(l) = B'_T_'(l)'^2^'. | TT_2_TT is the usual W'_TT_'(l) = B'_T_'(l)'^2^'. | ||
# second extension, named 'EE', contains the 9 fields 'EE_2_TT', 'EE_2_EE', 'EE_2_BB', ... for leakage of EE towards TT, EE, BB, ... | # second extension, named 'EE', contains the 9 fields 'EE_2_TT', 'EE_2_EE', 'EE_2_BB', ... for leakage of EE towards TT, EE, BB, ... | ||
# 3rd extension: 'BB' with 'BB_2_TT', ... | # 3rd extension: 'BB' with 'BB_2_TT', ... | ||
# 4th extension: 'TE' with 'TE_2_TT', ... | # 4th extension: 'TE' with 'TE_2_TT', ... | ||
| − | # %item value=0% (there is no extension #5 nor 6, corresponding to TB and EB, since these terms are unlikely | + | # %item value=0% (there is no extension #5 nor 6, corresponding to TB and EB, since these terms are unlikely |
| − | to be major sources of contamination for the other spectra) | + | to be major sources of contamination for the other spectra)<br /> |
[==] | [==] | ||
| − | The measured C'^*^'(l) are then related to the sky ones C(l) | + | The measured C'^*^'(l) are then related to the sky ones C(l)<br /> |
| − | C'^TT*^'(l) = C'^TT^'(l) TT_2_TT(l) + C'^EE^'(l) EE_2_TT(l) + C'^BB^'(l) BB_2_TT(l) + C'^TE^'(l) TE_2_TT(l) | + | C'^TT*^'(l) = C'^TT^'(l) TT_2_TT(l) + C'^EE^'(l) EE_2_TT(l) + C'^BB^'(l) BB_2_TT(l) + C'^TE^'(l) TE_2_TT(l) <br /> |
| − | C'^EE*^'(l) = C'^TT^'(l) TT_2_EE(l) + C'^EE^'(l) EE_2_EE(l) + C'^BB^'(l) BB_2_EE(l) + C'^TE^'(l) TE_2_EE(l) | + | C'^EE*^'(l) = C'^TT^'(l) TT_2_EE(l) + C'^EE^'(l) EE_2_EE(l) + C'^BB^'(l) BB_2_EE(l) + C'^TE^'(l) TE_2_EE(l) <br /> |
| − | C'^TE*^'(l) = C'^TT^'(l) TT_2_TE(l) + C'^EE^'(l) EE_2_TE(l) + C'^BB^'(l) BB_2_TE(l) + C'^TE^'(l) TE_2_TE(l) | + | C'^TE*^'(l) = C'^TT^'(l) TT_2_TE(l) + C'^EE^'(l) EE_2_TE(l) + C'^BB^'(l) BB_2_TE(l) + C'^TE^'(l) TE_2_TE(l) <br /> |
| − | C'^ET*^'(l) = C'^TT^'(l) TT_2_ET(l) + C'^EE^'(l) EE_2_ET(l) + C'^BB^'(l) BB_2_ET(l) + C'^TE^'(l) TE_2_ET(l) | + | C'^ET*^'(l) = C'^TT^'(l) TT_2_ET(l) + C'^EE^'(l) EE_2_ET(l) + C'^BB^'(l) BB_2_ET(l) + C'^TE^'(l) TE_2_ET(l) <br /> |
... | ... | ||
| − | ** These FITS files contain the same information as the raw npz files above, with the added value that the matrix elements | + | ** These FITS files contain the same information as the raw npz files above, with the added value that the matrix elements <br /> |
have been re-scaled so that ''B'_T_'(l=0)'' = 1 (a relative shift < 10'^-3^' in power). | have been re-scaled so that ''B'_T_'(l=0)'' = 1 (a relative shift < 10'^-3^' in power). | ||
** To read these FITS file in IDL or python, see [[http://wiki.planck.fr/index.php/Proc/InstrumentModels#tools]] | ** To read these FITS file in IDL or python, see [[http://wiki.planck.fr/index.php/Proc/InstrumentModels#tools]] | ||
Revision as of 09:35, 16 February 2018
Beam window functions have computed with the Febecop Pipeline (as described there), and the QuickPol pipeline (see Hivon et al, 2017[1], and the Planck 2016 Likelihood paper[2]).
The beam window functions relate, over the full sky or over a masked sky, the angular power spectrum measured (in the absence of noise) on a map produced by a set of detectors , to the true underlying sky angular power spectrum (assumed to have isotropic statistical properties, as is the case for the CMB).
Contents
QuickPol effective beam window products[edit]
They are available in two forms:
Beam window functions[edit]
such that
for X=T, E or B, and where is the pixel window function, which depends on the resolution parameter Nside (=2048 for Planck HFI maps).
They are provided in FITS files, in a format compatible with HEALPix tools such as synfast and smoothing, as well as with PolSpice.
Beam matrices[edit]
, such that
for X,Y,X',Y'= T, E or B.
They are provided in FITS files, containing 4 extensions each:
- first one, named 'TT', contains the 9 fields: 'TT_2_TT', 'TT_2_EE', 'TT_2_BB', 'TT_2_TE', 'TT_2_TB', 'TT_2_EB', 'TT_2_ET', 'TT_2_BT', 'TT_2_BE'
describing the ℓ-dependent leakage template of TT towards TT, EE, BB, ... respectively.
TT_2_TT is the usual W'_TT_'(l) = B'_T_'(l)'^2^'.
- second extension, named 'EE', contains the 9 fields 'EE_2_TT', 'EE_2_EE', 'EE_2_BB', ... for leakage of EE towards TT, EE, BB, ...
- 3rd extension: 'BB' with 'BB_2_TT', ...
- 4th extension: 'TE' with 'TE_2_TT', ...
- %item value=0% (there is no extension #5 nor 6, corresponding to TB and EB, since these terms are unlikely
to be major sources of contamination for the other spectra)
[==]
The measured C'^*^'(l) are then related to the sky ones C(l)
C'^TT*^'(l) = C'^TT^'(l) TT_2_TT(l) + C'^EE^'(l) EE_2_TT(l) + C'^BB^'(l) BB_2_TT(l) + C'^TE^'(l) TE_2_TT(l)
C'^EE*^'(l) = C'^TT^'(l) TT_2_EE(l) + C'^EE^'(l) EE_2_EE(l) + C'^BB^'(l) BB_2_EE(l) + C'^TE^'(l) TE_2_EE(l)
C'^TE*^'(l) = C'^TT^'(l) TT_2_TE(l) + C'^EE^'(l) EE_2_TE(l) + C'^BB^'(l) BB_2_TE(l) + C'^TE^'(l) TE_2_TE(l)
C'^ET*^'(l) = C'^TT^'(l) TT_2_ET(l) + C'^EE^'(l) EE_2_ET(l) + C'^BB^'(l) BB_2_ET(l) + C'^TE^'(l) TE_2_ET(l)
...
- These FITS files contain the same information as the raw npz files above, with the added value that the matrix elements
- These FITS files contain the same information as the raw npz files above, with the added value that the matrix elements
have been re-scaled so that B'_T_'(l=0) = 1 (a relative shift < 10'^-3^' in power).
- To read these FITS file in IDL or python, see [[1]]
References[edit]
- ↑ Hivon E., Mottet, S. & Ponthieu N., 2017 QuickPol: Fast calculation of effective beam matrices for CMB polarization A&A 598, A25, 2017A&A...598A..25H
- ↑ Planck collaboration, 2018, Planck 2016 results. V. Legacy Power Spectra and Likelihoods
Cosmic Microwave background
(Planck) High Frequency Instrument
Flexible Image Transfer Specification
