Difference between revisions of "HFI performance summary"

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The extreme sensitivity provided by the 100 mK bolometers and the HFI architecture provided a new view of the submillimetre and millimetre sky, with a noise level not far from the fundamental limits set by the photon noise of the observed source. However, expected and unexpected systematic effects were seen, the most noticeable of them being the spikes in the signal produced by cosmic rays hitting the bolometers and their immediate surroundings.
 
The extreme sensitivity provided by the 100 mK bolometers and the HFI architecture provided a new view of the submillimetre and millimetre sky, with a noise level not far from the fundamental limits set by the photon noise of the observed source. However, expected and unexpected systematic effects were seen, the most noticeable of them being the spikes in the signal produced by cosmic rays hitting the bolometers and their immediate surroundings.
  
The noise performance of the HFI bolometers is measured on timelines which have been cleaned of features such as glitches, and from which the signal has been removed. The figures below show an example (from {{PlanckPapers|planck2011-1-6}})  of this process.
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The noise performance of the HFI bolometers is measured on timelines which have been cleaned of features such as glitches, and from which the signal has been removed. The cleaning process has evolved overtime and the measured noise characteristics have correspondingly changed. The diagram below (from {{PlanckPapers|planck2011-1-6}} illustrates the main steps of the cleaning process.
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[[File:Screen Shot 2018-06-22 at 09.12.06.png]]
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The figures below show examples (from {{PlanckPapers|planck2011-1-6}})  of the cleaning and signal removal process.
 
[[File:toi_hfi.png|center]]
 
[[File:toi_hfi.png|center]]
 
[[File:[[File:Screen Shot 2018-06-21 at 20.17.40.png|center]]
 
[[File:[[File:Screen Shot 2018-06-21 at 20.17.40.png|center]]
 
[[File:Screen Shot 2018-06-21 at 20.17.58.png|center]]
 
[[File:Screen Shot 2018-06-21 at 20.17.58.png|center]]
  
The cleaning process has evolved overtime and the measured noise characteristics have correspondingly changed. The diagram below (from {{PlanckPapers|planck2011-1-6}} illustrates the main steps of the cleaning process.
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The two tables below give two snapshots of the evolution of the noise estimation. The first table (from {{PlanckPapers|planck2013-p06}}) applies to the 2013 release products, and the second table (from {{PlanckPapers|planck2014-a07}}) applies to the 2015 and 2018 release products.
 
 
[[File:Screen Shot 2018-06-22 at 09.12.06.png]]
 
 
 
The two tables below give two snapshots of this evolution. The first table (from {{PlanckPapers|planck2013-p06}}) applies to the 2013 release products, and the second table (from {{PlanckPapers|planck2014-a07}}) applies to the 2015 and 2018 release products.
 
  
 
[[File:Screen Shot 2018-06-22 at 09.18.05.png]]
 
[[File:Screen Shot 2018-06-22 at 09.18.05.png]]
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The overall sensitivity for the 2013 release was around that announced as the goal in the [http://www.sciops.esa.int/SA/PLANCK/docs/Bluebook-ESA-SCI(2005)1_V2.pdf|"bluebook"] {{BibCite|planck2005-bluebook}} , i.e. 2 times better than the required sensitivity. These numbers improved by about √2 when the whole mission data become available.
 
The overall sensitivity for the 2013 release was around that announced as the goal in the [http://www.sciops.esa.int/SA/PLANCK/docs/Bluebook-ESA-SCI(2005)1_V2.pdf|"bluebook"] {{BibCite|planck2005-bluebook}} , i.e. 2 times better than the required sensitivity. These numbers improved by about √2 when the whole mission data become available.
  
After basic processing and cleaning, the bolometer noise power spectra contain non-white components, as can be seen in the following spectra (from {{PlanckPapers|planck2014-a07}}).
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After basic processing and cleaning, the bolometer noise power spectra still contain non-white components, as can be seen in the following spectra (from {{PlanckPapers|planck2014-a07}}).
  
 
[[File:Screen Shot 2018-06-22 at 09.48.57.png]]
 
[[File:Screen Shot 2018-06-22 at 09.48.57.png]]
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(*) These sensitivities are only valid for high Galactic latitude.
 
(*) These sensitivities are only valid for high Galactic latitude.
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During map-making, subtle systematic effects can be corrected to a much higher degree than at timeline level. This process is described in detail for the 2015 products in {{PlanckPapers|planck2014-a08}}  and for the 2018 products in {{PlanckPapers|planck2016-l03}}. Those papers contain full assessments of the remaining levels of systematic effects.
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==references==
 
==references==

Revision as of 08:20, 22 June 2018

The HFI operated flawlessly for 30 months, the maximum autonomy expected for the helium of the dilution cooler. The telescope pointing was achieved with an accuracy better than expected and reconstructed to a few seconds of arc. Fifty of the 52 bolometers collected data in very stable conditions during the whole mission, and practically all of the data were correctly recorded.

The extreme sensitivity provided by the 100 mK bolometers and the HFI architecture provided a new view of the submillimetre and millimetre sky, with a noise level not far from the fundamental limits set by the photon noise of the observed source. However, expected and unexpected systematic effects were seen, the most noticeable of them being the spikes in the signal produced by cosmic rays hitting the bolometers and their immediate surroundings.

The noise performance of the HFI bolometers is measured on timelines which have been cleaned of features such as glitches, and from which the signal has been removed. The cleaning process has evolved overtime and the measured noise characteristics have correspondingly changed. The diagram below (from Planck-Early-V[1] illustrates the main steps of the cleaning process.

Screen Shot 2018-06-22 at 09.12.06.png

The figures below show examples (from Planck-Early-V[1]) of the cleaning and signal removal process.

Toi hfi.png

[[File:

Screen Shot 2018-06-21 at 20.17.40.png
Screen Shot 2018-06-21 at 20.17.58.png

The two tables below give two snapshots of the evolution of the noise estimation. The first table (from Planck-2013-XII[2]) applies to the 2013 release products, and the second table (from Planck-2015-A06[3]) applies to the 2015 and 2018 release products.

Screen Shot 2018-06-22 at 09.18.05.png Screen Shot 2018-06-22 at 09.22.34.png

The overall sensitivity for the 2013 release was around that announced as the goal in the "bluebook" [4] , i.e. 2 times better than the required sensitivity. These numbers improved by about √2 when the whole mission data become available.

After basic processing and cleaning, the bolometer noise power spectra still contain non-white components, as can be seen in the following spectra (from Planck-2015-A06[3]).

Screen Shot 2018-06-22 at 09.48.57.png

The noise characteristics also vary slightly during the mission, as can be seen in the following spectra (from Planck-2015-A06[3]).

Screen Shot 2018-06-22 at 09.53.46.png


Average characteristics of the HFI can also be estimated at map level. The table below gathers parameters based on the 2013 release. The sensitivity here is obtained from the half difference of the half rings.

Beam size and sensitivity of maps for the nominal mission (15 months)
Frequency 100 GHz 143 GHz 217 GHz 353 GHz 545 GHz 857 GHz
Beam size [FWHM, arcmin] 9.66 7.27 5.01 4.86 4.84 4.63
Sensitivity per fiducial pixel 3.95 µK/K 2.35 µK/K 4.58 µK/K 15.17 µK/K 0.013 MJy sr-1 (*) 0.013 MJy sr-1 (*)
Goal sensitivity 2.5 µK/K 2.2 µK/K 4.8 µK/K 14.7 µK/K 0.023 MJy sr-1 0.041 MJy sr-1

(*) These sensitivities are only valid for high Galactic latitude.

During map-making, subtle systematic effects can be corrected to a much higher degree than at timeline level. This process is described in detail for the 2015 products in Planck-2015-A07[5] and for the 2018 products in Planck-2020-A3[6]. Those papers contain full assessments of the remaining levels of systematic effects.


references[edit]

  1. 1.01.1 Planck early results. V. The Low Frequency Instrument data processing, A. Zacchei, D. Maino, C. Baccigalupi, et al. , A&A, 536, A5, (2011).
  2. Planck 2013 results. XI. Component separation, Planck Collaboration, 2014, A&A, 571, A11.
  3. 3.03.13.2 Planck 2015 results. VI. LFI mapmaking, Planck Collaboration, 2016, A&A, 594, A6.
  4. The Scientific Programme of Planck, Planck Collaboration, ESA publication ESA-SCI(2005)/01, (2005).
  5. Planck 2015 results. VII. High Frequency Instrument data processing: Time-ordered information and beam processing, Planck Collaboration, 2016, A&A, 594, A7.
  6. Planck 2018 results. III. High Frequency Instrument data processing and frequency maps, Planck Collaboration, 2020, A&A, 641, A3.

(Planck) High Frequency Instrument

Full-Width-at-Half-Maximum

European Space Agency