Difference between revisions of "Catalogues"
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|PROB_COLCOL || real*8 || || Colour-colour selection probability | |PROB_COLCOL || real*8 || || Colour-colour selection probability | ||
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|DIST_OPT_EXT_DR7 || real*8 || kpc || Distance estimate [2] using optical extinction on SDSS DR7 | |DIST_OPT_EXT_DR7 || real*8 || kpc || Distance estimate [2] using optical extinction on SDSS DR7 |
Revision as of 05:33, 11 October 2016
Contents
(2015) Second Catalogue of Compact Sources (PCCS2 & PCCS2E)[edit]
The second Planck Catalogue of Compact Sources (PCCS2) is a set of single-frequency source catalogues extracted from the Planck full-mission maps in intensity and polarization (LFI_SkyMap_0??_1024_R2.01_full.fits and HFI_SkyMap_???_2048_R2.00_full.fits). The catalogues have been constructed as described in PCCS and in section 2 of Planck-2015-A26[1]. The validation of the catalogues is described in section 3 of Planck-2015-A26[1].
The catalogue at 100 GHz and above has been divided into two sub-catalogues: the PCCS2, here the sources have been detected in regions of the sky where it is possible to estimate the reliability of the detections, either statistically or by using external catalogues; PCCS2, here the detected sources are located in regions of the sky where it is not possible to make an estimate of their reliability.
By definition, the reliability of the whole PCCS2 is ≥ 80%, and a flag is available that allows the user to select a subsample of sources with a higher level of reliability (e.g., 90% or 95%).
The nine Planck full-mission frequency channel maps are used as input to the source detection pipelines. They contain 48 months of data for LFI channels and 29 months of data for HFI channels. Therefore the flux densities of sources obtained from the full-mission maps are the average of at least 8 observations for LFI channels or at least 4 observations for HFI channels. The relevant properties of the frequency maps and main parameters used to generate the catalogues are summarized in Tables 1 and 2.
Four different photometry methods have been used. For one of the methods, the native photometry from the Mexican hat wavelet detection algorithm, the analysis is performed on patches containing tangent plane projections of the map. For the other methods (aperture photometry, point spread function fitting, and Gaussian fitting), the analysis is performed directly on the full-sky maps.
The analysis in polarization has been performed in a non-blind fashion, looking at the position of the sources previously detected in intensity. As a result, polarization flux densities and polarization angles have been measured for hundreds of sources with a significance >99.99%. This high threshold in significance has been chosen to minimize the possibility of misinterpreting a peak of the polarized background as a source. This implies that, in general, most of the polarized sources are very bright, introducing an additional selection effect.
Channel | 30 | 44 | 70 | 100 | 143 | 217 | 353 | 545 | 857 |
---|---|---|---|---|---|---|---|---|---|
Frequency [GHz] | 28.4 | 44.1 | 70.4 | 100.0 | 143.0 | 217.0 | 353.0 | 545.0 | 857.0 |
Wavelength [μm] | 10561 | 6807 | 4260 | 3000 | 2098 | 1382 | 850 | 550 | 350 |
Number of sources | |||||||||
PCCS2 | 1560 | 934 | 1296 | 1742 | 2160 | 2135 | 1344 | 1694 | 4891 |
PCCS2E | — | — | — | 2487 | 4139 | 16842 | 22665 | 31068 | 43290 |
Union PCCS2+PCCS2E | — | — | — | 4229 | 6299 | 18977 | 24009 | 32762 | 48181 |
Number of sources in the extragalactic zonea. | |||||||||
PCCS2 | 745 | 367 | 504 | 1742 | 2160 | 2135 | 1344 | 1694 | 4891 |
PCCS2E | — | — | — | 0 | 0 | 26 | 289 | 839 | 2097 |
Union PCCS2+PCSS2E | — | — | — | 1742 | 2160 | 2161 | 1633 | 2533 | 6988 |
Flux densities [mJy] in the extragalactic zonea . | |||||||||
PCCS2 | |||||||||
minimumb | 376 | 603 | 444 | 232 | 147 | 127 | 242 | 535 | 720 |
90% completeness | 426 | 676 | 489 | 269 | 177 | 152 | 304 | 555 | 791 |
uncertainty | 87 | 134 | 101 | 55 | 35 | 29 | 55 | 105 | 168 |
PCCS2E | |||||||||
minimumb | — | — | — | — | — | 189 | 350 | 597 | 939 |
90% completeness | — | — | — | — | — | 144 | 311 | 557 | 927 |
uncertainty | — | — | — | — | — | 35 | 73 | 144 | 278 |
Table 1 Notes
a 30-70 GHz: the extragalactic zone is given by |b| > 30°. 100-857 GHz: outside of galactic region where the reliability cannot be accurately assessed. Note that for the PCCS2E the only sources which occur in this region lie in the filament mask.
b Minimum flux density of the catalogue in the extragalactic zone after excluding the faintest 10% of sources.
Channel | 30 | 44 | 70 | 100 | 143 | 217 | 353 |
---|---|---|---|---|---|---|---|
Number of significantly polarized sources in PCCS2 | 122 | 30 | 34 | 20 | 25 | 11 | 1 |
Minimum polarized flux densitya [mJy] | 117 | 181 | 284 | 138 | 148 | 166 | 453 |
Polarized flux density uncertainty [mJy] | 46 | 88 | 91 | 30 | 26 | 30 | 81 |
Minimum polarized flux density completeness 90% [mJy] | 199 | 412 | 397 | 135 | 100 | 136 | 347 |
Minimum polarized flux density completeness 95% [mJy] | 251 | 468 | 454 | 160 | 111 | 153 | 399 |
Minimum polarized flux density completeness 100% [mJy] | 600 | 700 | 700 | 250 | 147 | 257 | 426 |
Number of significantly polarized sources in PCCS2E | — | — | — | 43 | 111 | 325 | 666 |
Minimum polarized flux densitya [mJy] | — | — | — | 121 | 87 | 114 | 348 |
Polarized flux density uncertainty [mJy] | — | — | — | 52 | 44 | 55 | 178 |
Minimum polarized flux density completeness 90% [mJy] | — | — | — | 410 | 613 | 270 | 567 |
Minimum polarized flux density completeness 95% [mJy] | — | — | — | 599 | 893 | 464 | 590 |
Minimum polarized flux density completeness 100% [mJy] | — | — | — | 835 | 893 | 786 | 958 |
Table 2 Notes
a Minimum polarized flux density of the catalogue of significantly polarised sources after excluding the faintest 10% of sources.
Catalogues[edit]
The PCCS2 catalogues are contained in the FITS files:
- COM_PCCS_030_R2.04.fits
- COM_PCCS_044_R2.04.fits
- COM_PCCS_070_R2.04.fits
- COM_PCCS_100_R2.01.fits
- COM_PCCS_143_R2.01.fits
- COM_PCCS_217_R2.01.fits
- COM_PCCS_353_R2.01.fits
- COM_PCCS_545_R2.01.fits
- COM_PCCS_857_R2.01.fits
and the PCCS2E catalogues are contained in the FITS files:
- COM_PCCS_100-excluded_R2.01.fits
- COM_PCCS_143-excluded_R2.01.fits
- COM_PCCS_217-excluded_R2.01.fits
- COM_PCCS_353-excluded_R2.01.fits
- COM_PCCS_545-excluded_R2.01.fits
- COM_PCCS_857-excluded_R2.01.fits
The structure of these files is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument (LFI / HFI) | |
VERSION | String | Version of PCCS (PCCS2 / PCCS2_E) | |
DATE | String | Date file created: yyyy-mm-dd | |
ORIGIN | String | Name of organization responsible for the data (LFI-DPC / HFI-DPC) | |
TELESCOP | String | Telescope (PLANCK) | |
CREATOR | String | Pipeline Version | |
DATE-OBS | String | days | Beginning of the survey: yyyy-mm-dd |
DATE-END | String | days | End of the survey: yyyy-mm-dd |
FWHM | Real*4 | arcmin | FWHM from an elliptical Gaussian fit to the effective beam |
OMEGA_B | Real*4 | arcmin2 | Area of the effective beam |
FWHM_EFF | Real*4 | arcmin | FWHM computed from OMEGA_B assuming beam is Gaussian |
OMEGA_B1 | Real*4 | arcmin2 | Beam area within a radius of 1 × FWHM_EFF |
OMEGA_B2 | Real*4 | arcmin2 | Beam area within a radius of 2 × FWHM_EFF |
Extension 1: BINTABLE, EXTNAME = PCCS2_fff (where fff is the frequency channel) | |||
Column Name | Data Type | Units | Description |
Identification | |||
NAME | String | Source name (see note 1) | |
Source position | |||
GLON | Real*8 | degrees | Galactic longitude based on extraction algorithm |
GLAT | Real*8 | degrees | Galactic latitude based on extraction algorithm |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON,GLAT) |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON,GLAT) |
Photometry | |||
DETFLUX | Real*4 | mJy | Flux density of source as determined by detection method |
DETFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from detection method |
APERFLUX | Real*4 | mJy | Flux density of source as determined from the aperture photometry |
APERFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from the aperture photometry |
PSFFLUX | Real*4 | mJy | Flux density of source as determined from PSF fitting |
PSFFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from PSF fitting |
GAUFLUX | Real*4 | mJy | Flux density of source as determined from 2-D Gaussian fitting |
GAUFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from 2-D Gaussian fitting |
GAU_SEMI1 | Real*4 | arcmin | Gaussian fit along axis 1 (FWHM; see note 2 for axis definition) |
GAU_SEMI1_ERR | Real*4 | arcmin | Uncertainty (1 sigma) in derived Gaussian fit along axis 1 |
GAU_SEMI2 | Real*4 | arcmin | Gaussian fit along axis 2 (FWHM) |
GAU_SEMI2_ERR | Real*4 | arcmin | Uncertainty (1 sigma) in derived Gaussian fit along axis 2 |
GAU_THETA | Real*4 | deg | Gaussian fit orientation angle (see note 2) |
GAU_THETA_ERR | Real*4 | deg | Uncertainty (1 sigma) in derived gaussian fit orientation angle |
GAU_FWHM_EFF | Real*4 | arcmin | Gaussian fit effective FWHM |
Polarization measurements (30-353 GHz only) | |||
P | Real*4 | mJy | Polarization flux density of the sources as determined by a matched filter (see note 3) |
P_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived polarization flux density (see note 3) |
ANGLE_P | Real*4 | degrees | Orientation of polarization with respect to NGP (see notes 2 and 3) |
ANGLE_P_ERR | Real*4 | degrees | Uncertainty (1 sigma) in orientation of polarization (see note 3) |
APER_P | Real*4 | mJy | Polarization flux density of the sources as determined by aperture photometry (see note 3) |
APER_P_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived polarization flux density (see note 3) |
APER_ANGLE_P | Real*4 | degrees | Orientation of polarization with respect to NGP (see notes 2 and 3) |
APER_ANGLE_P_ERR | Real*4 | degrees | Uncertainty (1 sigma) in orientation of polarization (see note 3) |
P_UPPER_LIMIT | Real*4 | mJy | Polarization flux density 99.99% upper limit. This is provided only when P column is set to NULL; otherwise this column itself contains a NULL. |
APER_P_UPPER_LIMIT | Real*4 | mJy | Polarization flux density 99.99% upper limit. This is provided only when APER_P column is set to NULL; otherwise this column itself contains a NULL. |
Marginal polarization measurements (100-353 GHz only) – see note 4 | |||
P_STAT | Integer*2 | Polarization detection status | |
PX | Real*4 | mJy | Polarization flux density of the sources as determined by a matched filter using Bayesian polarization estimator. |
PX_ERR_LOWER | Real*4 | mJy | PX uncertainty; lower 95% error bar |
PX_ERR_UPPER | Real*4 | mJy | PX uncertainty; upper 95% error bar |
ANGLE_PX | Real*4 | degrees | Orientation of polarization with respect to NGP using Bayesian polarization estimator (see note 2) |
ANGLE_PX_ERR_LOWER | Real*4 | degrees | ANGLE_PX uncertainty; lower 95% error bar |
ANGLE_PX_ERR_UPPER | Real*4 | degrees | ANGLE_PX uncertainty; upper 95% error bar |
Flags and validation | |||
EXTENDED | Integer*2 | Extended source flag (see note 5) | |
EXT_VAL | Integer*2 | External validation flag (see note 6) | |
ERCSC | String | Name of the ERCSC counterpart, if any | |
PCCS | String | Name of the PCCS counterpart, if any | |
Flags and validation (PCCS2 only) | |||
HIGHEST_RELIABILITY_CAT | Integer*4 | See note 7 | |
Flags and validation (PCCS2E 100-857 GHz only) | |||
WHICH_ZONE | Integer*2 | See note 8 | |
Flags and validation (217-857 GHz only) | |||
CIRRUS_N | Integer*2 | Number of sources (S/N > 5) detected at 857 GHz within a 1-degree radius. | |
SKY_BRIGHTNESS | Real*4 | MJy/sr | The mean 857 GHz brightness within a 2-degree radius. This may be used as another indicator of cirrus contamination. |
Flux densities at other frequencies (857 GHz only) | |||
APERFLUX_217 | Real*4 | mJy | Estimated flux density at 217 GHz |
APERFLUX_ERR_217 | Real*4 | mJy | Uncertainty in flux density at 217 GHz |
APERFLUX_353 | Real*4 | mJy | Estimated flux density at 353 GHz |
APERFLUX_ERR_353 | Real*4 | mJy | Uncertainty in flux density at 353 GHz |
APERFLUX_545 | Real*4 | mJy | Estimated flux density at 545 GHz |
APERFLUX_ERR_545 | Real*4 | mJy | Uncertainty in flux density at 545 GHz |
Notes
- Format is PCCS2 fff Glll.ll±bb.bb for sources in the PCCS2 and PCCS2E fff Glll.ll±bb.bb for sources in the PCCS2E, where fff is the frequency channel and (l, b) is the position of the source in Galactic coordinates truncated to two decimal places.
- We follow the IAU/IEEE convention (Hamaker & Bregman 1996) for defining the angle of polarization of a source, and this convention is also used for the other angles in the catalogue. The angle is measured from the North Galactic Pole in a clockwise direction from -90 to 90 degrees.
- Provided when the significance of the polarization measurement is > 99.99% and set to NULL otherwise.
- The P_STAT flag gives the status of the marginal polarization detection, possible values are:
- 3 – Bright: P field filled in; all PX fields set to NULL.
- 2 – Significant: P field is set to NULL; 0 is outside the PX 95% HPD; all PX fields are filled.
- 1 – Marginal: P field is set to NULL; 0 is inside the PX 95% HPD, but mode of PX posterior distribution is not 0; all PX fields are filled.
- 0 – No detection: P field is set to NULL; mode of PX posterior distribution is 0; PX_ERRL, ANGLE_PX, ANGLE_PX_ERR_LOWER, and ANGLE_PX_ERR_UPPER are set to NULL.
- The EXTENDED flag has the value of 0 if the source is compact and the value of 1 is it extended. The source size is determined by the geometric mean of the Gaussian fit FWHMs, with the criterion for extension being sqrt(GAU_FWHMMAJ * GAU_FWHMIN) > 1.5 times the beam FWHM.
- The EXT_VAL flag gives the status of the external validation, possible values are:
- 3 – The source has a clear counterpart in one of the catalogues used as ancillary data.
- 2 – The source does not have a clear counterpart in one of the catalogues used as ancillary data but it has been detected by the internal multi-frequency method.
- 1 – The source does not have a clear counterpart in one of the catalogues used as ancillary data and it has not been detected by the internal multi-frequency method, but it has been detected in a previous Planck source catalogue.
- 0 – The source does not have a clear counterpart in one of the catalogues used as ancillary data and it has not been detected by the internal multi-frequency method.
- The HIGHEST_RELIABILTY_CAT column contains the highest reliability catalogue to which the source belongs. As the full catalogue reliability is ≥ 80%, this is the lowest possible value in this column. Where possible this is provided in steps of 1% otherwise it is in steps of 5%.
- The WHICH_ZONE column encodes the zone in which the source lies:
- 1 – source lies inside filament mask.
- 2 – source lies inside Galactic zone.
- 3 – sources lies in both filament mask and Galactic zone.
Zone map[edit]
For each HFI frequency channel there is an associated map which defines the quantified-reliability (PCCS2) and unquantified-reliability (PCCS2E) zones are on the sky.
The files are called:
- COM_PCCS_100-zoneMask_R2.01.fits
- COM_PCCS_143-zoneMask_R2.01.fits
- COM_PCCS_217-zoneMask_R2.01.fits
- COM_PCCS_353-zoneMask_R2.01.fits
- COM_PCCS_545-zoneMask_R2.01.fits
- COM_PCCS_857-zoneMask_R2.01.fits
The structure of the files is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
DATE | String | Date of creation of file | |
Extension 1: BINTABLE, HEALPix map (see note 1) | |||
FITS keyword | Data Type | Value | Description |
PIXTYPE | String | HEALPIX | HEALPix pixelation |
ORDERING | String | RING | Pixel ordering |
NSIDE | Int*4 | 2048 | HEALPix resolution parameter |
NPIX | Int*4 | 50331648 | Number of pixels |
COORDSYS | String | G | Coordinate system |
FREQ_CHL | String | Frequency channel |
Notes
- This FITS extension contains an integer HEALPix map which encodes the information on which of 4 possible regions on the sky each pixel belongs to:
- 0 – quantified-reliability zone (PCCS2).
- 1 – filament mask.
- 2 – Galactic zone.
- 3 – filament mask and Galactic zone.
S/N threshold map[edit]
For each HFI frequency channel there are a number of maps which contains the S/N threshold used to accept sources into the PCCS2 and PCCS2E catalogues.
For the full catalogue (80% reliability in the quantified reliability zone) they are:
- COM_PCCS_100-SN-threshold_R2.01.fits
- COM_PCCS_143-SN-threshold_R2.01.fits
- COM_PCCS_217-SN-threshold_R2.01.fits
- COM_PCCS_353-SN-threshold_R2.01.fits
- COM_PCCS_545-SN-threshold_R2.01.fits
- COM_PCCS_857-SN-threshold_R2.01.fits
For 85% reliability they are:
- COM_PCCS_100-SN-threshold-85pc-reliability_R2.01.fits
- COM_PCCS_143-SN-threshold-85pc-reliability_R2.01.fits
- COM_PCCS_217-SN-threshold-85pc-reliability_R2.01.fits
- COM_PCCS_353-SN-threshold-85pc-reliability_R2.01.fits
- COM_PCCS_545-SN-threshold-85pc-reliability_R2.01.fits
- COM_PCCS_857-SN-threshold-85pc-reliability_R2.01.fits
For 90% reliability they are:
- COM_PCCS_100-SN-threshold-90pc-reliability_R2.01.fits
- COM_PCCS_143-SN-threshold-90pc-reliability_R2.01.fits
- COM_PCCS_217-SN-threshold-90pc-reliability_R2.01.fits
- COM_PCCS_353-SN-threshold-90pc-reliability_R2.01.fits
- COM_PCCS_545-SN-threshold-90pc-reliability_R2.01.fits
- COM_PCCS_857-SN-threshold-90pc-reliability_R2.01.fits
For 95% reliability they are:
- COM_PCCS_100-SN-threshold-95pc-reliability_R2.01.fits
- COM_PCCS_143-SN-threshold-95pc-reliability_R2.01.fits
- COM_PCCS_217-SN-threshold-95pc-reliability_R2.01.fits
- COM_PCCS_353-SN-threshold-95pc-reliability_R2.01.fits
- COM_PCCS_545-SN-threshold-95pc-reliability_R2.01.fits
- COM_PCCS_857-SN-threshold-95pc-reliability_R2.01.fits
The structure of the files is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
DATE | String | Date of creation of file | |
Extension 1: BINTABLE, HEALPix map (see note 1) | |||
FITS keyword | Data Type | Value | Description |
PIXTYPE | String | HEALPIX | HEALPix pixelation |
ORDERING | String | RING | Pixel ordering |
NSIDE | Int*4 | 2048 | HEALPix resolution parameter |
NPIX | Int*4 | 50331648 | Number of pixels |
COORDSYS | String | G | Coordinate system |
FREQ_CHL | String | Frequency channel |
Notes
- This FITS extension contains a single precision HEALPix map of the S/N threshold applied in the generation of the catalogue at that position on the sky.
Noise map[edit]
For each HFI frequency channel there is an associated map which contains the detection noise as a function of position on the sky.
The files are called:
- COM_PCCS_100-noise-level_R2.01.fits
- COM_PCCS_143-noise-level_R2.01.fits
- COM_PCCS_217-noise-level_R2.01.fits
- COM_PCCS_353-noise-level_R2.01.fits
- COM_PCCS_545-noise-level_R2.01.fits
- COM_PCCS_857-noise-level_R2.01.fits
The structure of the files is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
DATE | String | Date of creation of file | |
Extension 1: BINTABLE, HEALPix map (see note 1) | |||
FITS keyword | Data Type | Value | Description |
PIXTYPE | String | HEALPIX | HEALPix pixelation |
ORDERING | String | RING | Pixel ordering |
NSIDE | Int*4 | 2048 | HEALPix resolution parameter |
NPIX | Int*4 | 50331648 | Number of pixels |
COORDSYS | String | G | Coordinate system |
FREQ_CHL | String | Frequency channel |
Notes
- This FITS extension contains a single precision HEALPix map of the detection noise at each location on the sky, in units of Jy.
Previous releases: (2013) PCCS and (2011) ERCSC[edit]
Second Planck Release (2013): Description of the PCCS
The Catalogue of Compact Sources
Product description
The PCCS is a set of nine single-frequencies lists of sources extracted from the Planck nominal mission data. By definition its reliability is > 80% and a special effort was made to use simple selection procedures in order to facilitate statistical analyses. With a common detection method for all the channels and the additional three photometries, spectral analysis can also be done safely. The deeper completeness levels and, as a consequence, the higher number of sources compared with its predecessor the ERCSC, will allow the extension of previous studies to more sources and to fainter flux densities. The PCCS is the natural evolution of the ERCSC, but both lack polarization and multi-frequency information. Future releases will take advantage of the full mission data and they will contain information on properties of sources not available in this release, such as polarization, multi-frequency and variability.
Channel | 30 | 44 | 70 | 100 | 143 | 217 | 353 | 545 | 857 |
---|---|---|---|---|---|---|---|---|---|
Frequency [GHz] | 28.4 | 44.1 | 70.4 | 100.0 | 143.0 | 217.0 | 353.0 | 545.0 | 857.0 |
Beam FWHM1 [arcmin] | 32.38 | 27.10 | 13.30 | 9.88 | 7.18 | 4.87 | 4.65 | 4.72 | 4.39 |
SNR threshold | 4.0 | 4.0 | 4.0 | 4.6 | 4.7 | 4.8 | 4.92/6.03 | 4.7/7.0 | 4.9/7.0 |
# of detections | 1256 | 731 | 939 | 3850 | 5675 | 16070 | 17689 | 26472 | 35719 |
# of detections for |b| > 30º) | 572 | 258 | 332 | 845 | 1051 | 1901 | 2035 | 4164 | 7851 |
Flux density uncertainty [mJy] | 109 | 198 | 149 | 61 | 38 | 35 | 74 | 132 | 189 |
Min flux density4 [mJy] | 461 | 825 | 566 | 266 | 169 | 149 | 298 | 479 | 671 |
90% completeness [mJ] | 575 | 1047 | 776 | 300 | 190 | 180 | 330 | 570 | 680 |
Position uncertainty5 [arcmin] | 1.8 | 2.1 | 1.4 | 1.0 | 0.7 | 0.7 | 0.8 | 0.5 | 0.4 |
Notes
- The Planck beams are described in Planck-2013-IV[2] and Planck-2013-VII[3]. This table shows the values which were adopted for the PCCS (derived from the effective beams).
- In the extragalactic zone (48% of the sky; see Fig. 2 in Planck-2013-XXVIII[4]).
- In the Galactic zone (52% of the sky; see Fig. 2 in Planck-2013-XXVIII[4]).
- Minimum flux density of the catalogue at |b| > 30º after excluding the 10% faintest sources.
- Positional uncertainty derived by comparison with PACO sample ([5][6][7]) up to 353 GHz and with Herschel samples (HRS, KINGFISH, HeViCS, H-ATLAS) in the other channels.
Before using the PCCS, please read the Cautionary Notes in the PCCS general description section. For full details, see paper Planck-2013-XXVIII[4].
Production process
For a description of the production and validation processes of the PCCS see the corresponding section.
Inputs
The data obtained from the Planck nominal mission between (2009 August 12 and 2010 November 27) have been processed into full-sky maps by the HFI and LFI Data Processing Centres (DPCs). A description of the processing can be found in Planck-2013-II[8] and Planck-2013-VI[9]. The data consist of two complete sky surveys and 60% of the third survey. This implies that the flux densities of sources obtained from the nominal mission maps are the average of at least two observations. The nine Planck frequency channel maps are used as input to the source detection pipelines. The relevant properties of the frequency maps and main parameters used to generate the catalogues are summarized in Table 1.
The input data used to generate this product are the following:
Related products
Other products that are related and share some commonalities with the product being described here are the other catalogues:
File names
- COM_PCCS_030_R1.30.fits
- COM_PCCS_044_R1.30.fits
- COM_PCCS_070_R1.30.fits
- COM_PCCS_100_R1.20.fits
- COM_PCCS_143_R1.20.fits
- COM_PCCS_217_R1.20.fits
- COM_PCCS_353_R1.20.fits
- COM_PCCS_545_R1.20.fits
- COM_PCCS_857_R1.20.fits
Meta Data
The PCCS source list in each frequency is structured as a FITS binary table having one row for each detected source. The details of the FITS file structure are below
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | LFI or HFI | |
VERSION | String | Version of PCCS | |
DATE | String | Date file created:yyyy-mm-dd | |
ORIGIN | String | Name of organization responsible for the data (LFI-DPC – HFI-DPC) | |
TELESCOP | String | PLANCK | |
CREATOR | String | Pipeline Version | |
DATE-OBS | String | days | Start-up time of the survey: yyyy-mm-dd |
DATE-END | String | days | Ending time of the survey: yyyy-mm-dd |
Extension 1: (BINTABLE) | |||
Column Name | Data Type | Units | Description |
Identification | |||
NAME | String | Source name (Note 1) | |
Source Position | |||
GLON | Real*8 | degrees | Galactic longitude based on extraction algorithm |
GLAT | Real*8 | degrees | Galactic latitude based on extraction algorithm |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON,GLAT) |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON,GLAT) |
Photometry | |||
DETFLUX | Real*4 | mJy | Flux density of source as determined by detection method |
DETFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from detection method |
APERFLUX | Real*4 | mJy | Flux density of source as determined from the aperture photometry |
APERFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from the aperture photometry |
PSFFLUX | Real*4 | mJy | Flux density of source as determined from PSF fitting |
PSFFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from PSF fitting |
GAUFLUX | Real*4 | mJy | Flux density of source as determined from 2-D Gaussian fitting |
GAUFLUX_ERR | Real*4 | mJy | Uncertainty (1 sigma) in derived flux density from 2-D Gaussian fitting |
GAU_SEMI1 | Real*4 | arcmin | Gaussian fit along axis 1 (FWHM; see Note 4 for axis definition) |
GAU_SEMI1_ERR | Real*4 | arcmin | Uncertainty (1 sigma) in derived Gaussian fit along axis 1 |
GAU_SEMI2 | Real*4 | arcmin | Gaussian fit along axis 2 (FWHM) |
GAU_SEMI2_ERR | Real*4 | arcmin | Uncertainty (1 sigma) in derived Gaussian fit along axis 2 |
GAU_THETA | Real*4 | deg | Gaussian fit orientation angle (Note 4) |
GAU_THETA_ERR | Real*4 | deg | Uncertainty (1 sigma) in derived gaussian fit orientation angle |
GAU_FWHM_EFF | Real*4 | arcmin | Gaussian fit effective FWHM |
Flags and validation | |||
EXTENDED | Integer*2 | Extended source flag (Note 2) | |
CIRRUS_N | Integer*2 | Number of sources detected at 857 GHz within 1 degree | |
EXT_VAL | Integer*2 | External validation flag (Note 3) | |
ERCSC | String | Name of the ERCSC counterpart if any | |
ONLY 857 GHz Catalogue | |||
APERFLUX_217 | Real*4 | mJy | Estimated flux density at 217 GHz |
APERFLUX_ERR_217 | Real*4 | mJy | Uncertainty in source flux density at 217 GHz |
APERFLUX_353 | Real*4 | mJy | Estimated flux density at 353 GHz |
APERFLUX_ERR_353 | Real*4 | mJy | Uncertainty in source flux density at 353 GHz |
APERFLUX_545 | Real*4 | mJy | Estimated flux density at 545 GHz |
APERFLUX_ERR_545 | Real*4 | mJy | Uncertainty in source flux density at 545 GHz |
Notes
- Source names consist of a prefix and a position. The prefix used is PCCS1 fff for the catalogue at fff GHz. The position is in Galactic coordinates and specified as "Glll.ll±bb.bb" where the (l,b) values are truncated to two decimal places. For example, a source detected at (l,b) = (120.237, 4.231) in the 545 GHz Planck map would be labelled PCCS1 545 G120.23±04.23.
- The EXTENDED flag has the value of 0 if the source is compact and the value of 1 is it extended. The source size is determined by the geometric mean of the Gaussian fit FWHMs, with the criteria for extension being sqrt(GAU_FWHMMAJ * GAU_FWHMIN) > 1.5 times the beam FWHM.
- The EXT_VAL flag takes the value of 0, 1, or 2, based on the following conditions:
- = 2: The source has a clear counterpart in one of the catalogues considered as ancillary data.
- = 1: The source has no clear counterpart in one of the ancillary catalogues but it has been detected by the internal multi-frequency method (LFI channels) or match with neighbouring frequencies, above or below (HFI channels).
- = 0: The source has no clear counterpart in one of the ancillary catalogues and it has not been detected by the internal multi-frequency method or neighbouring frequencies.
- The x-axis is defined for each source as parallel to the line of constant colatitude, with the same direction as the longitude. Therefore the position angles are measured anticlockwise from the y-axis.
References[edit]
- ↑ 1.01.1 Planck 2015 results. XXVI. The second Planck catalogue of compact sources, Planck Collaboration, 2016, A&A, 594, A26.
- ↑ Planck 2013 results. IV. Low Frequency Instrument beams and window functions, Planck Collaboration, 2014, A&A, 571, A4.
- ↑ Planck 2013 results. VII. HFI time response and beams, Planck Collaboration, 2014, A&A, 571, A7.
- ↑ 4.04.14.2 Planck 2013 results. XXVIII. The Planck Catalogue of Compact Sources, Planck Collaboration, 2014, A&A, 571, A28.
- ↑ The Planck-ATCA Co-eval Observations project: the brightsample, M. Massardi, A. Bonaldi, L. Bonavera, M. López-Caniego, G. de Zotti, R. D. Ekers, MNRAS, 415, 1597-1610, (2011).
- ↑ The Planck-ATCA Coeval Observations project: the faintsample, L. Bonavera, M. Massardi, A. Bonaldi, J. González-Nuevo, G. de Zotti, R. D. Ekers, MNRAS, 416, 559-566, (2011).
- ↑ The Planck-ATCA Co-eval Observations project: the spectrallyselected sample, A. Bonaldi, L. Bonavera, M. Massardi, G. De Zotti, MNRAS, 428, 1845-1854, (2013).
- ↑ Planck 2013 results. II. Low Frequency Instrument data processing, Planck Collaboration, 2014, A&A, 571, A2.
- ↑ Planck 2013 results. VI. High Frequency Instrument Data Processing, Planck Collaboration, 2014, A&A, 571, A6.
First Planck Release (2011): Description of the 2011 ERCSC (Early Compact Source, Cold Core and SZ Catalogues )
The ERCSC
The Plank Early Release Compact Source Catalogue was the first Planck product to be publicly released in Jan 2011. It was produced with a very rapid turnaround to facilitate follow-up observations with existing cryogenic observatories such as Herschel. It contained a list of all high reliability sources, both Galactic and extragalactic, that were derived from the first all sky coverage by Planck. i.e., using observations obtained from 12 August 2009 to 6 June 2010. Thus the full sky was covered once, and ~60% of the sky was covered twice. The goals were to achieve a photometric accuracy of 30% and a positional accuracy 1/5 of the beam FWHM in the RMS sense.
The ERCSC consisted of nine source lists, one at each of the nine Planck frequency channels. The number of sources in the lists range from 705 at 30 GHz to 8988 at 857 GHz. No attempt was made to cross-match the sources from the different frequencies due to the wide range of spatial resolutions (33 arcmin at 30 GHz to 4.3 arcmin at 857 GHz) spanned by Planck. Furthermore, a list of Cold Cores of interstellar molecular clouds within the Galaxy and a list of galaxy clusters detected through the Sunyaev- Zel’dovich effect (SZ), were also provided. These consisted of candidate sources that were detected using multifrequency algorithms that use the distinct spectral signature of such sources. The Cold Cores catalogue contained 915 sources while the SZ cluster catalogue consisted of 189 sources
In order to generate the ERCSC, four source detection algorithms were run as part of the ERCSC pipeline. A Monte-Carlo algorithm based on the injection and extraction of artificial sources into the Planck maps was implemented to select reliable sources among all extracted candidates such that the cumulative reliability of the catalogue is >90%. Reliability is defined as the fraction of sources in the catalog which have measured flux densities which are within 30% of their true flux density. There is no requirement on completeness for the ERCSC. As a result of the Monte-Carlo assessment of reliability of sources from the different techniques, an implementation of the PowellSnakes source extraction technique was used at the five frequencies between 30 and 143 GHz while the SExtractor technique was used between 217 and 857 GHz. The 10σ photometric flux density limit of the catalogue at $|b| > 30$ deg is 0.49, 1.0, 0.67, 0.5, 0.33, 0.28, 0.25, 0.47 and 0.82 Jy at each of the nine frequencies between 30 and 857GHz. Sources which are up to a factor of ~2 fainter than this limit, and which are present in "clean" regions of the Galaxy where the sky background due to emission from the interstellar medium is low, are included in the ERCSC if they meet the high reliability criterion. The sensitivity of the ERCSC is shown in the figure below. The ERCSC sources have known associations to stars with dust shells, stellar cores, radio galaxies, blazars, infrared luminous galaxies and Galactic interstellar medium features. A significant fraction of unclassified sources are also present in the catalogs.
The multifrequency information from Planck allows some basic classification of the sources to be undertaken. In the Galactic plane, at frequencies below 100 GHz, the majority of the sources are dominated by synchrotron or free-free emission. At the higher frequencies, the sources are almost exclusively dominated by thermal dust emission. At high Galactic latitudes however, the synchrotron sources dominate the source counts to 217 GHz with dusty sources being the primary source population at 353 GHz and higher. Recent attempts to classify a subset of the Planck 857 GHz sources at high latitudes based on cross-correlations with sources in other catalogs such as WISE and SDSS, found that almost half of them are associated with stars and low-redshift galaxies while a significant fraction (44%) might be interstellar medium features[1].
Full details on the construction, contents and usage of the ERCSC, ECC and ESZ catalogues can be found in Planck-Early-VII[2], Planck-Early-VIII[3], Planck-Early-XXIII[4].
The figure shows the ERCSC flux density limits, quanitfied as the faintest ERCSC source at |b|<10 deg (dashed black line) and at |b|>30 deg (solid black line), compared to those of other wide area surveys (Planck-Early-VII[2]). Also shown are spectra of known sources of foreground emission as red lines. The ERCSC sensitivity is worse in the Galactic plane due to the strong contribution of ISM emission, especially at submillimeter wavelengths. At face value, the WMAP and Planck flux density limits appear to be comparable at the lowest frequencies, but the Planck ERCSC is much more complete as discussed in Planck-Early-VII[2].
References[edit]
- ↑ Classification of Compact Submillimeter Sources in the Planck Archive, C. H. Johnson, C. Border, K. O'Connor, D. Rothrock, R. Chary, M. Bingham, M. Clark, M. Ernst, S. Gilbert, S. Koop, M. Maddaus, I. Miller, A. O'Bryan, T. Ravelomanantsoa, D. San Miguel, L. Schmidt, E. Searls, W. Tong, O. Torres, A. Zeidner, NITARP, in American Astronomical Society Meeting Abstracts American Astronomical Society Meeting Abstracts, 221, 352.18, (2013).
- ↑ 2.02.12.2 Planck early results. VII. The Early Release Compact Source Catalogue, Planck Collaboration VII, A&A, 536, A7, (2011).
- ↑ Planck early results. VIII. The all-sky early Sunyaev-Zeldovich cluster sample, Planck Collaboration VIII, A&A, 536, A8, (2011).
- ↑ Planck early results. XXIII. The Galactic cold core population revealed by the first all-sky survey, Planck Collaboration XXIII, A&A, 536, A23, (2011).
(2015) Second SZ Catalogue[edit]
The Planck SZ catalogue is constructed as described in SZ catalogue and in sections 2 and 3 of Planck-2015-A27[1]. Three pipelines are used to detect SZ clusters: two independent implementations of the Matched Multi-Filter (MMF1 and MMF3), and PowellSnakes (PwS). The main catalogue is constructed as the union of the catalogues from the three detection methods. The completeness and reliability of the catalogues have been assessed through internal and external validation as described in section 4 of Planck-2015-A27[1].
The size of a detection is given in terms of the scale size, θs, and the flux is given in terms of the total integrated Comptonization parameter, Y = Y5R500. The parameters of the GNFW profile assumed by the detection pipelines are written in the headers of the catalogues. For the sake of convenience, the conversion factor from Y to Y500 is also provided in the header.
The union catalogue contains the coordinates of a detection, its signal-to-noise ratio, an estimate of Y and its uncertainty, together with a summary of the validation information, including external identification of a cluster and its redshift if they are available. The pipeline from which the information is taken is called the reference pipeline. If more than one pipeline makes the same detection, the information is taken from the the pipeline that makes the most significant detection. Where the redshift is known, we provide the SZ mass for the reference pipeline.
The individual catalogues contain the coordinates and the signal-to-noise ratio of the detections, and information on the size and flux of the detections. The entries are cross-referenced to the detections in the union catalogue. The full information on the degeneracy between θs and Y is included in the individual catalogues in the form of the two-dimensional probability distribution for each detection. It is computed on a well-sampled grid to produce a two-dimensional image for each detection. It is provided in this form so it can be combined with a model or external data to produce tighter constraints on the parameters. The individual catalogues also contain Planck measurements of the SZ mass observable, MSZ, as calculated using a Y-M scaling relation and an assumed redshift to break the Y-θs degeneracy. These are provided for each detection as functions of assumed redshift, in the range 0.01 < z < 1, along with the upper and lower 68% confidence limits.
The selection function of the union catalogue, the intersection catalogue and the individual catalogues are provided in additional files. The selection function files contains the probability of detection for clusters of given intrinsic parameters θ500 and Y500. The file includes the definition of the survey area in the form of a HEALPix mask, and is evaluated for a range of signal-to-noise thresholds between 4.5 and 10.
Union catalogue[edit]
The union catalogue is contained in HFI_PCCS_SZ-union_R2.08.fits.
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument (HFI) | |
VERSION | String | Version of catalogue | |
DATE | String | Date file created: yyyy-mm-dd | |
ORIGIN | String | Name of organization responsible for the data (HFI-DPC) | |
TELESCOP | String | Telescope (PLANCK) | |
CREATOR | String | Pipeline version | |
DATE-OBS | String | Start date of the survey: yyyy-mm-dd | |
DATE-END | String | End date of the survey: yyyy-mm-dd | |
PROCVER | String | Data version | |
PP_ALPHA | Real*4 | GNFW pressure profile α parameter | |
PP_BETA | Real*4 | GNFW pressure profile β parameter | |
PP_GAMMA | Real*4 | GNFW pressure profile γ parameter | |
PP_C500 | Real*4 | GNFW pressure profile c500 parameter | |
PP_Y2YFH | Real*4 | Conversion factor from Y to Y500 | |
Extension 1: BINTABLE, EXTNAME = PSZ2_UNION | |||
Column Name | Data Type | Units | Description |
INDEX | Int*4 | Index used to cross-reference with individual catalogues | |
NAME | String | Source name (see note 1) | |
GLON | Real*8 | degrees | Galactic longitude |
GLAT | Real*8 | degrees | Galactic latitude |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON,GLAT) |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON,GLAT) |
POS_ERR | Real*4 | arcmin | Position uncertainty (95% confidence interval) |
SNR | Real*4 | Signal-to-noise ratio of the detection | |
PIPELINE | Int*4 | Pipeline from which information is taken (reference pipeline): 1= MMF1; 2 = MMF3; 3 = PwS | |
PIPE_DET | Int*4 | Pipelines which detect this object (see note 2) | |
PCCS2 | Bool | Indicates whether detection matches with any in PCCS2 catalogues | |
PSZ | Int*4 | Index of matching detection in PSZ1, or -1 if new detection | |
IR_FLAG | Int*1 | Flag denoting heavy infrared contamination | |
Q_NEURAL | Real*4 | Neural network quality flag (see note 3) | |
Y5R500 | Real*4 | 10-3 arcmin2 | Mean marginal Y5R500 as determined by reference pipeline |
Y5R500_ERR | Real*4 | 10-3 arcmin2 | Uncertainty on Y5R500 as determined by reference pipeline |
VALIDATION | Int*4 | External validation status (see note 4) | |
REDSHIFT_ID | String | External identifier of cluster associated with redshift measurement (see note 5) | |
REDSHIFT | Real*4 | Redshift of cluster (see note 5) | |
MSZ | Real*4 | 1014 Msol | SZ mass proxy (see note 6) |
MSZ_ERR_UP | Real*4 | 1014 Msol | Upper bound of 68% SZ mass proxy confidence interval (see note 6) |
MSZ_ERR_LOW | Real*4 | 1014 Msol | Lower bound of 68% SZ mass proxy confidence interval (see note 6) |
MCXC | String | Identifier of X-ray counterpart in the MCXC, if one is present | |
REDMAPPER | String | Identifier of optical counterpart in the RedMAPPer catalogue, if one is present | |
ACT | String | Identifier of SZ counterpart in the ACT catalogues, if one is present | |
SPT | String | Identifier of SZ counterpart in the SPT catalogues, if one is present | |
WISE_FLAG | Int*4 | Confirmation flag of WISE overdensity (see note 7) | |
AMI_EVIDENCE | Real*4 | Bayesian evidence for AMI counterpart detection (see note 8) | |
COSMO | Bool | Indicates whether detection is in the cosmology sample | |
COMMENT | String | Comments on this detection |
Notes
- Format is PSZ2 Glll.ll±bb.b where (l,b) are the Galactic coordinates truncated to 2 decimal places.
- The three least significant decimal digits are used to represent detection or non-detection by the pipelines. Order of the digits: hundreds = MMF1; tens = MMF3; units = PwS. If it is detected then the corresponding digit is set to 1, otherwise it is set to 0.
- Neural network quality flag is 1-Qbad, following the definitions in Aghanim et al. 2014.
- Summary of the external validation, encoding the most robust external identification: 10 = ENO follow-up; 11 = RTT follow-up; 12 = PanSTARRs; 13 = RedMAPPer non-blind; 14 = SDSS high-z; 15 = AMI; 16 = WISE; 20 = legacy identification from the PSZ1; 21 = MCXC; 22 = SPT; 23 = ACT; 24 = RedMAPPer; 25 = legacy identification from PSZ1 with externally updated redshift; 30 = NED; -1 = no known external counterpart.
- Redshift source is the most robust external identification listed in the VALIDATION field.
- MSZ is the hydrostatic mass assuming the best-fit Y-M scaling relation of Arnaud 2010 as a prior. The uncertainties are statistical and based on the Planck measurement uncertainties only. Not included in the uncertainties are the statistical errors on the scaling relation, the intrinsic scatter in the relation, or systematic errors in data selection for the scaling relation fit.
- Assigned by visual inspection: 0 = no significant galaxy overdensity; 1 = possible galaxy overdensity; 2 = probable galaxy overdensity; 3 = significant galaxy overdensity detected; -1 = possible galaxy overdensity (affected by bright star artefacts); -2 = no significant galaxy overdensity (affected by bright star artefacts); -3 = no assessment possible (affected by bright star artefacts); -10 = not analysed.
- Defined in the paper.
Individual catalogues[edit]
The individual pipeline catalogues are contained in the FITS files
- HFI_PCCS_SZ-MMF1_R2.08.fits (MMF1 pipeline)
- HFI_PCCS_SZ-MMF3_R2.08.fits (MMF3 pipeline)
- HFI_PCCS_SZ-PwS_R2.08.fits (PowellSnakes pipeline)
Their structure is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument (HFI) | |
VERSION | String | Version of catalogue | |
DATE | String | Date file created: yyyy-mm-dd | |
ORIGIN | String | Name of organization responsible for the data (HFI-DPC) | |
TELESCOP | String | Telescope (PLANCK) | |
CREATOR | String | Pipeline version | |
DATE-OBS | String | Start time of the survey: yyyy-mm-dd | |
DATE-END | String | End time of the survey: yyyy-mm-dd | |
PROCVER | String | Data version | |
PP_ALPHA | Real*4 | GNFW pressure profile α parameter | |
PP_BETA | Real*4 | GNFW pressure profile β parameter | |
PP_GAMMA | Real*4 | GNFW pressure profile γ parameter | |
PP_C500 | Real*4 | GNFW pressure profile c500 parameter | |
PP_Y2YFH | Real*4 | Conversion factor from Y to Y500 | |
Extension 1: BINTABLE, EXTNAME = PSZ2_INDIVIDUAL | |||
Column Name | Data Type | Units | Description |
INDEX | Int*4 | Index from union catalogue | |
NAME | String | Source name (see note 1) | |
GLON | Real*8 | degrees | Galactic longitude |
GLAT | Real*8 | degrees | Galactic latitude |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON, GLAT) |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON, GLAT) |
POS_ERR | Real*4 | arcmin | Position uncertainty (95% confidence interval) |
SNR | Real*4 | Signal-to-noise ratio of detection | |
TS_MIN | Real*4 | Minimum value of θs in grid in second extension HDU (see note 2) | |
TS_MAX | Real*4 | Maximum value of θs in grid in second extension HDU (see note 2) | |
Y_MIN | Real*4 | Minimum value of Y in grid in second extension HDU (see note 2) | |
Y_MAX | Real*4 | Maximum value of Y in grid in second extension HDU (see note 2) | |
Keyword | Data Type | Value | Description |
PIPELINE | String | Name of detection pipeline | |
Extension 2: IMAGE, EXTNAME = PSZ2_PROBABILITY (see note 2) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 256 | Dimension 1 |
NAXIS2 | Integer | 256 | Dimension 2 |
NAXIS3 | Integer | Ndet | Dimension 3 = Number of detections |
Keyword | Data Type | Value | Description |
PIPELINE | String | Name of detection pipeline | |
Extension 3: IMAGE, EXTNAME = PSZ2_MSZ_ARRAY (see note 3) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 100 | Dimension 1 |
NAXIS2 | Integer | 4 | Dimension 2 |
NAXIS3 | Integer | Ndet | Dimension 3 = Number of detections |
Keyword | Data Type | Value | Description |
PIPELINE | String | Name of detection pipeline |
Notes
- Format PSZ2 Glll.ll±bb.bb where (l, b) are the Galactic coordinates truncated to 2 decimal places.
- Extension 2 contains a three-dimensional image with the two-dimensional probability distribution in θs and Y for each detection. The probability distributions are evaluated on a 256 × 256 linear grid between the limits specified in extension 1. The limits are determined independently for each detection. The dimension of the 3D image is 256 × 256 × Ndet, where Ndet is the number of detections. The first dimension is θs and the second dimension is Y.
- Extension 3 contains a three-dimensional image with the information on the MSZ observable per cluster as a function of assumed redshift. The image dimensions are 100 × 4 × Ndet, where Ndet is the number of detections. The first dimension is the assumed redshift. The second dimension has size 4: the first element is the assumed redshift value corresponding to the MSZ values. The second element is the MSZ lower 68% confidence bound, the third element is the MSZ estimate and the fourth element is the MSZ upper 68% confidence bound, all in units of 1014 Msol. These uncertainties are based on the Planck measurement uncertainties only. Not included in the error estimates are the statistical errors on the scaling relation, the intrinsic scatter in the relation, or systematic errors in data selection for the scaling relation fit.
Selection function[edit]
The selection function for the union, intersection and individual pipeline catalogues are contained in the FITS files:
- HFI_PCCS_SZ-selfunc-union-survey_R2.08.fits (union catalogue, survey mask)
- HFI_PCCS_SZ-selfunc-union-cosmology_R2.08.fits (union catalogue, cosmology mask)
- HFI_PCCS_SZ-selfunc-intersec-survey_R2.08.fits (intersection catalogue, survey mask)
- HFI_PCCS_SZ-selfunc-intersec-cosmolog_R2.08.fits (intersection catalogue, cosmology mask)
- HFI_PCCS_SZ-selfunc-MMF1-survey_R2.08.fits (MMF1 catalogue, survey mask)
- HFI_PCCS_SZ-selfunc-MMF1-cosmolog_R2.08.fits (MMF1 catalogue, cosmology mask)
- HFI_PCCS_SZ-selfunc-MMF3-survey_R2.08.fits (MMF3 catalogue, survey mask)
- HFI_PCCS_SZ-selfunc-MMF3-cosmolog_R2.08.fits (MMF3 catalogue, cosmology mask)
- HFI_PCCS_SZ-selfunc-PwS-survey_R2.08.fits (PowellSnakes catalogue, survey mask)
- HFI_PCCS_SZ-selfunc-PwS-cosmolog_R2.08.fits (PowellSnakes catalogue, cosmology mask)
Their structure is as follows:
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument (HFI) | |
VERSION | String | Version of catalogue | |
DATE | String | Date file created: yyyy-mm-dd | |
ORIGIN | String | Name of organization responsible for the data (HFI-DPC) | |
TELESCOP | String | Telescope (PLANCK) | |
CREATOR | String | Pipeline version | |
DATE-OBS | String | Start time of the survey: yyyy-mm-dd | |
DATE-END | String | End time of the survey: yyyy-mm-dd | |
PROCVER | String | Data version | |
JOIN | String | Join type (UNION, INTERSEC, MMF1, MMF3, PwS) | |
MASK | String | Mask name (SURVEY, COSMOLOG) | |
Extension 1: BINTABLE, HEALPix map (see note 1) | |||
FITS keyword | Data Type | Value | Description |
PIXTYPE | String | HEALPIX | HEALPix pixelation |
ORDERING | String | RING | Pixel ordering |
NSIDE | Int*4 | 2048 | HEALPix resolution parameter |
NPIX | Int*4 | 50331648 | Number of pixels |
COORDSYS | String | G | Coordinate system |
Extension 2: IMAGE, EXTNAME = SELFUNC (see note 2) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 30 | Dimension 1 |
NAXIS2 | Integer | 32 | Dimension 2 |
NAXIS3 | Integer | 12 | Dimension 3 |
Keyword | Data Type | Value | Description |
AXIS1 | String | CY500 | Name of axis 1 |
AXIS2 | String | T500 | Name of axis 2 |
AXIS3 | String | SNRCUT | Name of axis 3 |
UNITS | String | PERCENT | Units of selection function |
COMPTYPE | String | DIFF | Type of selection function (differential) |
Extension 3: IMAGE, EXTNAME = YGRID (see note 3) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 30 | Dimension 1 |
Keyword | Data Type | Value | Description |
COL1 | String | CY500 | Grid values of Y500 |
Extension 4: IMAGE, EXTNAME = TGRID (see note 4) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 32 | Dimension 1 |
Keyword | Data Type | Value | Description |
COL1 | String | T500 | Grid values of θ500 |
Extension 5: IMAGE, EXTNAME = SNR_THRESH (see note 5) | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 12 | Dimension 1 |
Keyword | Data Type | Value | Description |
COL1 | String | S/N | Grid values of S/N threshold |
Notes
- Extension 1 contains a mask defining the survey region, given by an Nside = 2048 ring-ordered HEALPix map in GALACTIC coordinates. Pixels in the survey region have the value 1.0 while pixels outside of the survey region have value 0.0.
- Extension 2 contains a three-dimensional image containing the survey completeness probability distribution for various S/N thresholds. The information is stored in an image of size 30 × 32 × 12. The first dimension is Y500, the second dimension is θ500 and the third dimension is the signal-to-noise threshold. The units are percent and lie in the range 0-100 and denote the detection probability of a cluster in the given (Y500, θ500) bin.
- Extension 3 contains the Y500 grid values for the completeness data cube in the second extension. It has length 30 and spans the range from 1.12480 × 10-4 arcmin2 to 7.20325 × 10-2 arcmin2 in logarithmic steps.
- Extension 4 contains the θ500 grid values for the completeness data cube in the second extension. It has length 32 and spans the range from 0.9416 arcmin to 35.31 arcmin in logarithmic steps.
- Extension 5 contains the signal-to-noise threshold grid values for the completeness data cube in the second extension. It has length 12 and contains thresholds from 4.5 to 10.0 in steps of 0.5.
Previous releases: (2013) PSZ1[edit]
Second Planck Release (2013): Description of the Planck SZ Catalogue
The Planck SZ catalogue is constructed as described in SZ catalogue and in section 2 of Planck-2013-XXIX[2].
Three pipelines are used to detect SZ clusters: two independent implementations of the Matched Multi-Filter (MMF1 and MMF3), and PowellSnakes (PwS). The main catalogue is constructed as the union of the catalogues from the three detection methods. The individual catalogues are provided for the expert user in order to assess the consistency of the pipelines. The completeness and reliability of the catalogues have been assessed through internal and external validation as described in sections 3-6 of Planck-2013-XXIX[2].
The union catalogue contains the coordinates and the signal-to-noise ratio of the detections and a summary of the external validation information, including external identification of a cluster and its redshift if it is available.
The individual catalogues contain the coordinates and the signal-to-noise ratio of the detections, and information on the size and flux of the detections. The entries are cross-referenced to the detections in the union catalogue.
The size of a detection is given in terms of the scale size, $\theta_\mathrm{s}$, and the flux is given in terms of the total integrated Comptonization parameter, $Y = Y_{5r_{500}}$. The parameters of the GNFW profile assumed by the detection pipelines is written in the headers in the catalogues. For the sake of convenience, the conversion factor from $Y$ to $Y_{500}$ is also written in the header.
The full information on the degeneracy between $\theta_\mathrm{s}$ and $Y$ is included in the individual catalogues in the form of the two-dimensional probability distribution for each detection. It is computed on a well-sampled grid to produce a two-dimensional image for each detection. The degeneracy information is provided in this form so it can be combined with a model or external data to produce tighter constraints on the parameters.
Union Catalogue
The union catalogue is contained in COM_PCCS_SZ-union_R1.12.fits.
Extension 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument. | |
VERSION | String | Version of catalogue. | |
DATE | String | Date file created: yyyy-mm-dd. | |
ORIGIN | String | Name of organization responsible for the data. | |
TELESCOP | String | PLANCK. | |
CREATOR | String | Pipeline version. | |
DATE-OBS | String | Start time of the survey: yyyy-mm-dd. | |
DATE-END | String | End time of the survey: yyyy-mm-dd. | |
PROCVER | String | Data version. | |
PP_ALPHA | Real*4 | GNFW pressure profile $\alpha$ parameter. | |
PP_BETA | Real*4 | GNFW pressure profile $\beta$ parameter. | |
PP_GAMMA | Real*4 | GNFW pressure profile $\gamma$ parameter. | |
PP_C500 | Real*4 | GNFW pressure profile $c_{500}$ parameter. | |
PP_Y2YFH | Real*4 | Conversion factor from $Y$ to $Y_{500}$. | |
Extension 1: data extension (BINTABLE) | |||
Column Name | Data Type | Units | Description |
INDEX | Int*4 | Index. Used to cross-reference with individual catalogues. | |
NAME | String | Source name, (Note 1) | |
GLON | Real*8 | degrees | Galactic longitude. |
GLAT | Real*8 | degrees | Galactic latitude. |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON,GLAT). |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON,GLAT). |
POS_ERR | Real*4 | arcmin | Position uncertainty (approximate 68% confidence interval). See Caveats below. |
SNR | Real*4 | Signal-to-noise ratio of the detection. | |
PIPELINE | Int*4 | Souce pipeline: 1= MMF1; 2 = MMF3; 3 = PwS. | |
PIPE_DET | Int*4 | Pipelines which detect this object (note 2). | |
PCCS | Bool | Indicates whether detection matches any PCCS source. | |
VALIDATION | Int*4 | External validation status (Note 3) | |
ID_EXT | String | External identifier of cluster. | |
REDSHIFT | Real*4 | Redshift of cluster. | |
COSMO | Bool | Detection is in the cosmology sample. | |
COMMENT | Bool | Detection has a comment in the associated text file (Note 4). |
Notes
- format is PSZ1 Glll.ll+mn;bb.b where (l,b) are the Galactic and truncated to 2 decimal places.
- The three least significant decimal digits are used to represent detection or non-detection by the pipelines. Order of the digits: hundreds = MMF1; tens = MMF3; units = PwS. If it is detected then the corresponding digit is set to 1, otherwise it is set to 0.
- values are: 1 = candidate of class 1; 2 = candidate of class 2; 3 = candidate of class 3; 10 = Planck cluster confirmed by follow-up; 20 = known cluster.
- The comments on the detections in the catalogue are contained in a text file called COM_PCCS_SZ-union_comments_R1.11.txt, which contains one line for each detection in the union catalogue with COMMENT = T. The line starts with the INDEX and NAME of the detection to facilitate cross-referencing. The remainder of the line is the comment on that detection.
Individual Catalogues
The individual pipeline catalogues are contained in the FITS files
- COM_PCCS_SZ-MMF1_R1.11.fits (Matched Multi-Filter method #1)
- COM_PCCS_SZ-MMF3_R1.12.fits (Matched Multi-Filter method #3)
- COM_PCCS_SZ-PwS_R1.11.fits (Powell Snakes method)
Their structure is as follows:
Ext. 0: Primary header, no data | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
INSTRUME | String | Instrument. | |
VERSION | String | Version of catalogue. | |
DATE | String | Date file created: yyyy-mm-dd. | |
ORIGIN | String | Name of organization responsible for the data. | |
TELESCOP | String | PLANCK. | |
CREATOR | String | Pipeline version. | |
DATE-OBS | String | Start time of the survey: yyyy-mm-dd. | |
DATE-END | String | End time of the survey: yyyy-mm-dd. | |
PROCVER | String | Data version. | |
PP_ALPHA | Real*4 | GNFW pressure profile $\alpha$ parameter. | |
PP_BETA | Real*4 | GNFW pressure profile $\beta$ parameter. | |
PP_GAMMA | Real*4 | GNFW pressure profile $\gamma$ parameter. | |
PP_C500 | Real*4 | GNFW pressure profile $c_{500}$ parameter. | |
PP_Y2YFH | Real*4 | Conversion factor from $Y$ to $Y_{500}$. | |
Ext. 1: EXTNANE = PSZ_INDIVIDUAL (BINTABLE) | |||
Column Name | Data Type | Units | Description |
INDEX | Int*4 | Index from union catalogue. | |
NAME | String | Source name - see Note1 | |
GLON | Real*8 | degrees | Galactic longitude. |
GLAT | Real*8 | degrees | Galactic latitude. |
RA | Real*8 | degrees | Right ascension (J2000) transformed from (GLON,GLAT). |
DEC | Real*8 | degrees | Declination (J2000) transformed from (GLON,GLAT). |
POS_ERR | Real*4 | arcmin | Position uncertainty (approximate 68% confidence interval). See Caveats below. |
SNR | Real*4 | Signal-to-noise ratio of the detection. | |
SNR_COMPAT | Real*4 | SNR of the detection in compatibility mode (Note 2) | |
TS_MIN | Real*4 | Minimum value of $\theta_\mathrm{s}$ in grid in second extension HDU (see below). | |
TS_MAX | Real*4 | Maximum value of $\theta_\mathrm{s}$ in grid in second extension HDU (see below). | |
Y_MIN | Real*4 | Minimum value of $Y$ in grid in second extension HDU (see below). | |
Y_MAX | Real*4 | Maximum value of $Y$ in grid in second extension HDU (see below). | |
Keyword | Data Type | Value | Description |
PIPELINE | String | Name of detection pipeline. | |
Ext. 2: EXTNAME = PSZ_PROBABILITY (IMAGE) - Note 3 | |||
Keyword | Data Type | Value | Description |
NAXIS1 | Integer | 256 | Dim 1 |
NAXIS2 | Integer | 256 | Dim 2 |
NAXIS3 | Integer | Nsources | Dim 3 = Number of sources |
Keyword | Data Type | Value | Description |
PIPELINE | String | Name of detection pipeline. |
Notes
- Format PSZ1 Glll.ll±bb.bb where (l, b) are the Galactic coordinates truncated to 2 decimal places.
- For PwS, this is the S/N evaluated in a manner compatible with the MMF pipelines. For MMF1 and MMF3, it is identical to SNR.
- Ext. 2 contains a three-dimensional image with the two-dimensional probability distribution in $\theta_\mathrm{s}$ and $Y$ for each detection. The probability distributions are evaluated on a 256 × 256 linear grid between the limits specified in Ext. 1. The limits are determined independently for each detection. The dimension of the 3D image is 256 × 256 × n, where n is the number of detections. The first dimension is $\theta_\mathrm{s}$ and the second dimension is $Y$.
Mask
The mask used to construct the catalogue is contained in a file: COM_PCCS_SZ-unionMask_2048_R1.11.fits.
It is in GALACTIC coordinates, NESTED ordering, NSIDE=2048.
Additional information
A set of comments on the union catalogue is available in
Additional information on the SZ detections was retrieved from external sources and written into the FITS file
(for more details see Planck-2013-XXIX[2]). This file contains a single BINTABLE extension. The table contains 1 line per source, and the columns and their meaning are given below.
Ext. 0: (BINTABLE) | |||
---|---|---|---|
Column Name | Data Type | Units | Description |
INDEX | Int*4 | Index from union catalogue. | |
NAME | String | Source name in union catalogue | |
REDSHIFT | Real*4 | Redshift | |
REDSHIFT_SOURCE | Int*4 | Source for redshift - see Note 4. | |
ALT_NAME | String | Alternative names. | |
RA_MCXC | Real*4 | degrees | Right Ascension of the MCXC identifier. |
DEC_MCXC | Real*4 | degrees | Declination of the MCXC identifier. |
YZ_500 | Real*4 | 10-4 arcmin2 | Compton parameter in R500 from SZ-proxy. |
ERRP_YZ_500 | Real*4 | 10-4 arcmin2 | Error sup. in YZ_500 |
ERRM_YZ_500 | Real*4 | 10-4 arcmin2 | Error inf. in YZ_500 |
M_YZ_500 | Real*4 | 1014 Msol | Derived mass estimate (M_YZ_500) from SZ proxy. |
ERRP_M_YZ_500 | Real*4 | 1014 Msol | Error sup. on M_YZ_500. |
ERRM_M_YZ_500 | Real*4 | 1014 Msol | Error sup. on M_YZ_500. |
S_X | Real*4 | erg/s/cm2 | Unabsorbed X-ray flux - see Note 1. |
ERR_S_X | Real*4 | erg/s/cm2 | Error on unabsorbed X-ray flux. |
Y_PSX_500 | Real*4 | 10-4 arcmin2 | SZ signal for PSZ clusters identified with MCXC clusters- see Note 2. |
SN_PSX | Real*4 | Signal to noise for PSZ clusters identified with MCXC clusters - see Note 3. |
Notes
- Unabsorbed X-ray flux measured in an aperture of 5 arcmin in the band [0.1-2.4] keV. The aperture is centered on the Planck position, except for candidates associated with a BSC source for which we adopt the X-ray position. For sources with , we only quote an upper limit.
- SZ signal re-extracted fixing the size to the X-ray size provided in the MCXC catalogue at the X-ray position, for PSZ clusters identified with MCXC clusters.
- Computed in the Planck data at the X-ray position fixing the size to the X-ray size provided in the MCXC catalogue, for PSZ clusters identified with MCXC clusters.
- Source for redshifts:
-1 : No redshift available 1 : MCXC updated compilation[3] 2 : Databases NED and SIMBAD-CDS 3 : SDSS cluster catalogue[4] 4 : SDSS cluster catalogue[5] 5 : SPT[6][7][8][9][10][11][12] 6 : ACT[13][14][15][16] 7 : Search in SDSS galaxy catalogue from Planck Collab. 20 : XMM-Newton confirmation from Planck Collab. 50 : ENO-imaging confirmation from Planck Collab. 60 : WFI-imaging confirmation from Planck Collab. 65 : NTT-spectroscopic confirmation from Planck Collab. 500 : RTT-spectroscopic confirmation from Planck Collab. 600 : NOT-spectroscopic confirmation from Planck Collab. 650 : GEMINI-spectroscopic confirmation from Planck Collab. 700 : ENO-spectroscopic confirmation from Planck Collab.
Caveats
The following issue was found in Feb. 2014 in R1.11 of the MMF3 catalogue: the POS_ERR field values are overestimated by a factor 3.125 on average. This issue has been resolved in R1.12. A corrected version of the union catalogue has also been produced (also R1.12)
The approximate 68% (1-sigma) confidence interval in the POS_ERR field is computed as half of the 95% (2-sigma) confidence interval. Previously this was erroneously described as a 95% confidence interval.
(2015) Planck Catalogue of Galactic Cold Clumps[edit]
The Planck Catalogue of Galactic Cold Clumps (PGCC) is a list of 13188 Galactic sources and 54 sources located in the Small and Large Magellanic Clouds. The sources have been identified in Planck data as sources colder than their environment. It has been buit using the 48 months Planck data at 857, 545, and 353 GHz combined with the 3 THz IRAS data, as it is described in Planck-2015-A28[17].
The all-sky distribution of the PGCC sources is shown below on top of the 857 GHz emission shown in logarithmic scale between 10-2 to 102 MJy/sr.
Sources are divided into three categories based on the reliability of the flux density estimates in IRAS 3 THz and Planck 857, 545, and 353 GHz bands.
- FLUX_QUALITY=1 : sources with flux density estimates S/N > 1 in all bands ;
- FLUX_QUALITY=2 : sources with flux density estimates S/N > 1 only in 857, 545, and 353 GHz Planck bands, considered as very cold source candidates ;
- FLUX_QUALITY=3 : sources without any reliable flux density estimates, listed as poor candidates.
The all-sky distributions of the PGCC sources per FLUX_QUALITY category are shown below on top of the 857 GHz map in grey scale shown in logarithmic scale between 10-2 to 102 MJy/sr.
Distance estimates have been obtained on 5574 PGCC sources using seven different methods/technics, as described in Planck-2015-A28[17]. A flag is raised to quantify the quality of the distance estimates, defined as follows:
- DIST_QUALITY=0 : No distance estimate ;
- DIST_QUALITY=1 : Single distance estimate ;
- DIST_QUALITY=2 : Multiple distance estimates which are consistent within 1 ;
- DIST_QUALITY=3 : Multiple distance estimates which are not consistent within 1 ;
- DIST_QUALITY=4 : Single upper limits.
The all-sky distribution of the sources with robust distance estimates is shown below.
The catalogue is contained in the FITS file HFI_PCCS_GCC_R2.02.fits. It structure is as follows:
Identification | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
NAME | String | Source Name | |
SNR | real*8 | Maximum S/N over the 857, 545, and 353 GHz Planck cold residual maps | |
SNR_857 | real*8 | S/N of the cold residual detection at 857 GHz | |
SNR_545 | real*8 | S/N of the cold residual detection at 545 GHz | |
SNR_353 | real*8 | S/N of the cold residual detection at 353 GHz | |
Source position | |||
FITS Keyword | Data Type | Units | Description |
GLON | real*8 | deg | Galactic longitude based on morphology fitting |
GLAT | real*8 | deg | Galactic latitude based on morphology fitting |
RA | real*8 | deg | Right ascension (J2000) in degrees transformed from (GLON, GLAT) |
DEC | real*8 | deg | Declination (J2000) in degrees transformed from (GLON, GLAT) |
Morphology | |||
FITS Keyword | Data Type | Units | Description |
GAU_MAJOR_AXIS | real*8 | arcmin | FWHM along the major axis of the elliptical Gaussian |
GAU_MAJOR_AXIS_SIG | real*8 | arcmin | 1FWHM along the major axis | uncertainty on the
GAU_MINOR_AXIS | real*8 | arcmin | FWHM along the minor axis of the elliptical Gaussian |
GAU_MINOR_AXIS_SIG | real*8 | arcmin | 1FWHM along the minor axis | uncertainty on the
GAU_POSITION_ANGLE | real*8 | rad | Position angle of the elliptical gaussian (see note 1) |
GAU_POSITION_ANGLE_SIG | real*8 | rad | 1 | uncertainty on the position angle
Photometry | |||
FITS Keyword | Data Type | Units | Description |
FLUX_3000_CLUMP | real*8 | Jy | Flux density of the clump at 3 THz |
FLUX_3000_CLUMP_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the clump at 3 THz
FLUX_857_CLUMP | real*8 | Jy | Flux density of the clump at 857 GHz |
FLUX_857_CLUMP_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the clump at 857 GHz
FLUX_545_CLUMP | real*8 | Jy | Flux density of the clump at 545 GHz |
FLUX_545_CLUMP_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the clump at 545 GHz
FLUX_353_CLUMP | real*8 | Jy | Flux density of the clump at 353 GHz |
FLUX_353_CLUMP_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the clump at 353 GHz
FLUX_3000_WBKG | real*8 | Jy | Flux density of the warm background at 3 THz (see note 2) |
FLUX_3000_WBKG_SIG | real*8 | Jy | 1 | uncertainty on the flux density of warm background at 3 THz
FLUX_857_WBKG | real*8 | Jy | Flux density of the warm background at 857 GHz |
FLUX_857_WBKG_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the warm background at 857 GHz
FLUX_545_WBKG | real*8 | Jy | Flux density of the warm background at 545 GHz |
FLUX_545_WBKG_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the warm background at 545 GHz
FLUX_353_WBKG | real*8 | Jy | Flux density of the warm background at 353 GHz |
FLUX_353_WBKG_SIG | real*8 | Jy | 1 | uncertainty on the flux density of the warm background at 353 GHz
FLUX_QUALITY | int*4 | 1-3 | Category of flux density reliability (see note 3) |
FLUX_BLENDING | int*4 | 0/1 | 1 if blending issue with flux density estimate (see note 4) |
FLUX_BLENDING_IDX | int*8 | Catalogue index of the closest source responsible for blending | |
FLUX_BLENDING_ANG_DIST | real*8 | arcmin | Angular distance to the closest source responsible for blending |
FLUX_BLENDING_BIAS_3000 | real*8 | % | Relative bias of the flux density at 3000 GHz due to blending |
FLUX_BLENDING_BIAS_857 | real*8 | % | Relative bias of the flux density at 857 GHz due to blending |
FLUX_BLENDING_BIAS_545 | real*8 | % | Relative bias of the flux density at 545 GHz due to blending |
FLUX_BLENDING_BIAS_353 | real*8 | % | Relative bias of the flux density at 353 GHz due to blending |
Distance | |||
FITS Keyword | Data Type | Units | Description |
DIST_KINEMATIC | real*8 | kpc | Distance estimate [1] using kinematics |
DIST_KINEMATIC_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [1] using kinematics
DIST_OPT_EXT_DR7 | real*8 | kpc | Distance estimate [2] using optical extinction on SDSS DR7 |
DIST_OPT_EXT_DR7_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [2] using optical extinction on SDSS DR7
DIST_OPT_EXT_DR9 | real*8 | kpc | Distance estimate [3] using optical extinction on SDSS DR9 |
DIST_OPT_EXT_DR9_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [3] using optical extinction on SDSS DR9
DIST_NIR_EXT_IRDC | real*8 | kpc | Distance estimate [4] using near-infrared extinction towards IRDCs |
DIST_NIR_EXT_IRDC_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [4] using near-infrared extinction towards IRDCs
DIST_NIR_EXT | real*8 | kpc | Distance estimate [5] using near-infrared extinction |
DIST_NIR_EXT_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [5] using near-infrared extinction
DIST_MOLECULAR_COMPLEX | real*8 | kpc | Distance estimate [6] using molecular complex association |
DIST_MOLECULAR_COMPLEX_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [6] using molecular complex association
DIST_HKP_GCC | real*8 | kpc | Distance estimate [7] from the Herschel Key-Programme Galactic Cold Cores |
DIST_HKP_GCC_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [7] from the Herschel Key-Programme Galactic Cold Cores
DIST_OPTION | int*4 | 0-7 | Option of the best distance estimate used in other physical properties |
DIST_QUALITY | int*4 | 0-4 | Quality Flag of the consistency between distance estimates (see note 5) |
DIST | real*8 | kpc | Best distance estimate used for further physical properties |
DIST_SIG | real*8 | kpc | 1 | uncertainty on the best distance estimate
Temperature | |||
FITS Keyword | Data Type | Units | Description |
TEMP_CLUMP | real*8 | K | Temperature of the clump with | as a free parameter
TEMP_CLUMP_SIG | real*8 | K | 1 | uncertainty on the clump temperature with free
TEMP_CLUMP_LOW1 | real*8 | K | Lower 68% confidence limit of the clump temperature with | free
TEMP_CLUMP_UP1 | real*8 | K | Upper 68% confidence limit of the clump temperature with | free
BETA_CLUMP | real*8 | Spectral index | of the clump|
BETA_CLUMP_SIG | real*8 | 1 | uncertainty (from MCMC) on the emissivity spectral index of the clump|
BETA_CLUMP_LOW1 | real*8 | Lower 68% confidence limit of the emissivity spectral index | of the clump|
BETA_CLUMP_UP1 | real*8 | Upper 68% confidence limit of the emissivity spectral index | of the clump|
TEMP_BETA2_CLUMP | real*8 | K | Temperature of the clump with | = 2
TEMP_BETA2_CLUMP_SIG | real*8 | K | 1 | uncertainty on the temperature of the clump with = 2
TEMP_BETA2_CLUMP_LOW1 | real*8 | K | Lower 68% confidence limit of the clump temperature with | = 2
TEMP_BETA2_CLUMP_UP1 | real*8 | K | Upper 68% confidence limit of the clump temperature with | = 2
TEMP_WBKG | real*8 | K | Temperature of the warm background with | as a free parameter (see note 6)
TEMP_WBKG_SIG | real*8 | K | 1 | dispersion of the warm background temperature with free
TEMP_WBKG_LOW1 | real*8 | K | Lower 68% confidence limit of the warm background temperature with | free
TEMP_WBKG_UP1 | real*8 | K | Upper 68% confidence limit of the warm background temperature with | free
BETA_WBKG | real*8 | Spectral index | of the warm background (see note 6)|
BETA_WBKG_SIG | real*8 | 1 | uncertainty (from MCMC) of the emissivity spectral index of the warm background|
BETA_WBKG_LOW1 | real*8 | Lower 68% confidence limit of the emissivity spectral index | of the warm background|
BETA_WBKG_UP1 | real*8 | Upper 68% confidence limit of the emissivity spectral index | of the warm background|
TEMP_BETA2_WBKG | real*8 | K | Temperature of the warm background with | = 2
TEMP_BETA2_WBKG_SIG | real*8 | K | 1 | uncertainty on the temperature of the warm background with = 2
TEMP_BETA2_WBKG_LOW1 | real*8 | K | Lower 68% confidence limit of the warm background temperature with | = 2
TEMP_BETA2_WBKG_UP1 | real*8 | K | Upper 68% confidence limit of the warm background temperature with | = 2
Physical properties | |||
FITS Keyword | Data Type | Units | Description |
NH2 | real*8 | cm-2 | Column density | of the clump
NH2_SIG | real*8 | cm-2 | 1 | uncertainty on the column density
NH2_LOW[1,2,3] | real*8 | cm-2 | Lower 68%, 95% and 99% confidence limit of the column density |
NH2_UP[1,2,3] | real*8 | cm-2 | Upper 68%, 95% and 99% confidence limit of the column density |
MASS | real*8 | Mass estimate of the clump | |
MASS_SIG | real*8 | 1 | uncertainty on the mass estimate of the clump|
MASS_LOW[1,2,3] | real*8 | Lower 68%, 95% and 99% confidence limit of the mass estimate | |
MASS_UP[1,2,3] | real*8 | Upper 68%, 95% and 99% confidence limit of the mass estimate | |
DENSITY | real*8 | cm-3 | Mean density of the clump |
DENSITY_SIG | real*8 | cm-3 | 1 | uncertainty on the mean density estimate of the clump
DENSITY_LOW[1,2,3] | real*8 | cm-3 | Lower 68%, 95% and 99% confidence limit of the mean density estimate |
DENSITY_UP[1,2,3] | real*8 | cm-3 | Upper 68%, 95% and 99% confidence limit of the mean density estimate |
SIZE | real*8 | pc | Physical size of the clump |
SIZE_SIG | real*8 | pc | 1 | uncertainty on the physical size estimate of the clump
SIZE_LOW[1,2,3] | real*8 | pc | Lower 68%, 95% and 99% confidence limit of the physical size estimate |
SIZE_UP[1,2,3] | real*8 | pc | Upper 68%, 95% and 99% confidence limit of the physical size estimate |
LUMINOSITY | real*8 | Lo | Luminosity of the clump |
LUMINOSITY_SIG | real*8 | Lo | 1 | uncertainty on the luminosity estimate of the clump
LUMINOSITY_LOW[1,2,3] | real*8 | Lo | Lower 68%, 95% and 99% confidence limit of the luminosity estimate |
LUMINOSITY_UP[1,2,3] | real*8 | Lo | Upper 68%, 95% and 99% confidence limit of the luminosity estimate |
Flags | |||
FITS Keyword | Data Type | Units | Description |
XFLAG_LMC | int*4 | 0/1 | 1 if part of the LMC |
XFLAG_SMC | int*4 | 0/1 | 1 if part of the SMC |
XFLAG_ECC | int*4 | 0/1 | 1 if present in the ECC |
XFLAG_PCCS_857 | int*4 | 0/1 | 1 if present in the PCCS 857 GHz band |
XFLAG_PCCS_545 | int*4 | 0/1 | 1 if present in the PCCS 545 GHz band |
XFLAG_PCCS_353 | int*4 | 0/1 | 1 if present in the PCCS 353 GHz band |
XFLAG_PCCS_217 | int*4 | 0/1 | 1 if present in the PCCS 217 GHz band |
XFLAG_PCCS_143 | int*4 | 0/1 | 1 if present in the PCCS 143 GHz band |
XFLAG_PCCS_100 | int*4 | 0/1 | 1 if present in the PCCS 100 GHz band |
XFLAG_PCCS_70 | int*4 | 0/1 | 1 if present in the PCCS 70 GHz band |
XFLAG_PCCS_44 | int*4 | 0/1 | 1 if present in the PCCS 44 GHz band |
XFLAG_PCCS_30 | int*4 | 0/1 | 1 if present in the PCCS 30 GHz band |
XFLAG_PSZ | int*4 | 0/1 | 1 if present in the PCCS PSZ |
XFLAG_PHZ | int*4 | 0/1 | 1 if present in the PCCS HZ |
XFLAG_HKP_GCC | int*4 | 0/1 | 1 if present in the Herschel HKP-GCC |
Notes:
- 1: The position angle of the 2D ellipse is defined as the angle between the axis parallele to the Galactic plane and the major axis, counted clockwise.
- 2: The warm bakcground flux densities are computed using the same solid angle as for the clumps flux densities, but on the warm conponent map.
- 3: See text above for a full description of the FLUX_QUALITY flag, for which 1 is best.
- 4: This relative bias due to blending provides a rough estimate of the factor that should be applied on the clumpds flux densities to get a corrected estimate. It has been obtained on a very simple modelling of clumps morphology and the local environment. It has therefore to be taken very carefully.
- 5: See text above for a full description of the DIST_QUALITY flag.
- 6: Temperature and spectral index of the warm background are based on the warm background flux density estimates obtained on the same solid angle used for clumps
(2015) Planck List of high-redshift source candidates[edit]
The Planck list of high-redshift source candidates (PHZ) is a list of 2151 sources located in the cleanest 26% of the sky and identified as point sources exhibiting an excess in the submillimeter compared to their environment. It has been built using the 48 months Planck data at 857, 545, 353 and 217 GHz combined with the 3 THz IRAS data, as it is described in [18]. These sources are considered as high-z source candidates (z>1.5-2), given the very low contamination by Galactic cirrus.
Identification | |||
---|---|---|---|
FITS Keyword | Data Type | Units | Description |
NAME | String | Source Name | |
SNR_X545 | real*8 | S/N in the 545 GHz excess map | |
SNR_D857 | real*8 | S/N in the 857 GHz cleaned map | |
SNR_D545 | real*8 | S/N in the 545 GHz cleaned map | |
SNR_D353 | real*8 | S/N in the 353 GHz cleaned map | |
Source position | |||
FITS Keyword | Data Type | Units | Description |
GLON | real*8 | deg | Galactic longitude based on morphology fitting |
GLAT | real*8 | deg | Galactic latitude based on morphology fitting |
RA | real*8 | deg | Right ascension (J2000) in degrees transformed from (GLON, GLAT) |
DEC | real*8 | deg | Declination (J2000) in degrees transformed from (GLON, GLAT) |
Morphology | |||
FITS Keyword | Data Type | Units | Description |
GAU_MAJOR_AXIS | real*8 | arcmin | FWHM along the major axis of the elliptical Gaussian |
GAU_MAJOR_AXIS_SIG | real*8 | arcmin | 1FWHM along the major axis | uncertainty on the
GAU_MINOR_AXIS | real*8 | arcmin | FWHM along the minor axis of the elliptical Gaussian |
GAU_MINOR_AXIS_SIG | real*8 | arcmin | 1FWHM along the minor axis | uncertainty on the
GAU_POSITION_ANGLE | real*8 | rad | Position angle of the elliptical gaussian (see note 1) |
GAU_POSITION_ANGLE_SIG | real*8 | rad | 1 | uncertainty on the position angle
Photometry | |||
FITS Keyword | Data Type | Units | Description |
FLUX_CLEAN_857 | real*8 | Jy | Flux density of the clump at 857 GHz |
FLUX_CLEAN_857_SIG_SKY | real*8 | Jy | 1 | uncertainty at 857 GHz due to sky confusion
FLUX_CLEAN_857_SIG_DATA | real*8 | Jy | 1 | uncertainty at 857 GHz due to measurement error
FLUX_CLEAN_857_SIG_GEOM | real*8 | Jy | 1 | uncertainty at 857 GHz due to elliptical Gaussian fit accuracy
FLUX_CLEAN_545 | real*8 | Jy | Flux density of the clump at 545 GHz |
FLUX_CLEAN_545_SIG_SKY | real*8 | Jy | 1 | uncertainty at 545 GHz due to sky confusion
FLUX_CLEAN_545_SIG_DATA | real*8 | Jy | 1 | uncertainty at 545 GHz due to measurement error
FLUX_CLEAN_545_SIG_GEOM | real*8 | Jy | 1 | uncertainty at 545 GHz due to elliptical Gaussian fit accuracy
FLUX_CLEAN_353 | real*8 | Jy | Flux density of the clump at 353 GHz |
FLUX_CLEAN_353_SIG_SKY | real*8 | Jy | 1 | uncertainty at 353 GHz due to sky confusion
FLUX_CLEAN_353_SIG_DATA | real*8 | Jy | 1 | uncertainty at 353 GHz due to measurement error
FLUX_CLEAN_353_SIG_GEOM | real*8 | Jy | 1 | uncertainty at 353 GHz due to elliptical Gaussian fit accuracy
FLUX_CLEAN_217 | real*8 | Jy | Flux density of the clump at 217 GHz |
FLUX_CLEAN_217_SIG_SKY | real*8 | Jy | 1 | uncertainty at 217 GHz due to sky confusion
FLUX_CLEAN_217_SIG_DATA | real*8 | Jy | 1 | uncertainty at 217 GHz due to measurement error
FLUX_CLEAN_217_SIG_GEOM | real*8 | Jy | 1 | uncertainty at 217 GHz due to elliptical Gaussian fit accuracy
Physical Properties | |||
FITS Keyword | Data Type | Units | Description |
PROB_COLCOL | real*8 | Colour-colour selection probability | |
EBV_MEAN | real*8 | Mean extinction | within the source PSF|
DIST_OPT_EXT_DR7 | real*8 | kpc | Distance estimate [2] using optical extinction on SDSS DR7 |
DIST_OPT_EXT_DR7_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [2] using optical extinction on SDSS DR7
DIST_OPT_EXT_DR9 | real*8 | kpc | Distance estimate [3] using optical extinction on SDSS DR9 |
DIST_OPT_EXT_DR9_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [3] using optical extinction on SDSS DR9
DIST_NIR_EXT_IRDC | real*8 | kpc | Distance estimate [4] using near-infrared extinction towards IRDCs |
DIST_NIR_EXT_IRDC_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [4] using near-infrared extinction towards IRDCs
DIST_NIR_EXT | real*8 | kpc | Distance estimate [5] using near-infrared extinction |
DIST_NIR_EXT_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [5] using near-infrared extinction
DIST_MOLECULAR_COMPLEX | real*8 | kpc | Distance estimate [6] using molecular complex association |
DIST_MOLECULAR_COMPLEX_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [6] using molecular complex association
DIST_HKP_GCC | real*8 | kpc | Distance estimate [7] from the Herschel Key-Programme Galactic Cold Cores |
DIST_HKP_GCC_SIG | real*8 | kpc | 1 | uncertainty on the distance estimate [7] from the Herschel Key-Programme Galactic Cold Cores
DIST_OPTION | int*4 | 0-7 | Option of the best distance estimate used in other physical properties |
DIST_QUALITY | int*4 | 0-4 | Quality Flag of the consistency between distance estimates (see note 5) |
DIST | real*8 | kpc | Best distance estimate used for further physical properties |
DIST_SIG | real*8 | kpc | 1 | uncertainty on the best distance estimate
Temperature | |||
FITS Keyword | Data Type | Units | Description |
TEMP_CLUMP | real*8 | K | Temperature of the clump with | as a free parameter
TEMP_CLUMP_SIG | real*8 | K | 1 | uncertainty on the clump temperature with free
TEMP_CLUMP_LOW1 | real*8 | K | Lower 68% confidence limit of the clump temperature with | free
TEMP_CLUMP_UP1 | real*8 | K | Upper 68% confidence limit of the clump temperature with | free
BETA_CLUMP | real*8 | Spectral index | of the clump|
BETA_CLUMP_SIG | real*8 | 1 | uncertainty (from MCMC) on the emissivity spectral index of the clump|
BETA_CLUMP_LOW1 | real*8 | Lower 68% confidence limit of the emissivity spectral index | of the clump|
BETA_CLUMP_UP1 | real*8 | Upper 68% confidence limit of the emissivity spectral index | of the clump|
TEMP_BETA2_CLUMP | real*8 | K | Temperature of the clump with | = 2
TEMP_BETA2_CLUMP_SIG | real*8 | K | 1 | uncertainty on the temperature of the clump with = 2
TEMP_BETA2_CLUMP_LOW1 | real*8 | K | Lower 68% confidence limit of the clump temperature with | = 2
TEMP_BETA2_CLUMP_UP1 | real*8 | K | Upper 68% confidence limit of the clump temperature with | = 2
TEMP_WBKG | real*8 | K | Temperature of the warm background with | as a free parameter (see note 6)
TEMP_WBKG_SIG | real*8 | K | 1 | dispersion of the warm background temperature with free
TEMP_WBKG_LOW1 | real*8 | K | Lower 68% confidence limit of the warm background temperature with | free
TEMP_WBKG_UP1 | real*8 | K | Upper 68% confidence limit of the warm background temperature with | free
BETA_WBKG | real*8 | Spectral index | of the warm background (see note 6)|
BETA_WBKG_SIG | real*8 | 1 | uncertainty (from MCMC) of the emissivity spectral index of the warm background|
BETA_WBKG_LOW1 | real*8 | Lower 68% confidence limit of the emissivity spectral index | of the warm background|
BETA_WBKG_UP1 | real*8 | Upper 68% confidence limit of the emissivity spectral index | of the warm background|
TEMP_BETA2_WBKG | real*8 | K | Temperature of the warm background with | = 2
TEMP_BETA2_WBKG_SIG | real*8 | K | 1 | uncertainty on the temperature of the warm background with = 2
TEMP_BETA2_WBKG_LOW1 | real*8 | K | Lower 68% confidence limit of the warm background temperature with | = 2
TEMP_BETA2_WBKG_UP1 | real*8 | K | Upper 68% confidence limit of the warm background temperature with | = 2
Physical properties | |||
FITS Keyword | Data Type | Units | Description |
NH2 | real*8 | cm-2 | Column density | of the clump
NH2_SIG | real*8 | cm-2 | 1 | uncertainty on the column density
NH2_LOW[1,2,3] | real*8 | cm-2 | Lower 68%, 95% and 99% confidence limit of the column density |
NH2_UP[1,2,3] | real*8 | cm-2 | Upper 68%, 95% and 99% confidence limit of the column density |
MASS | real*8 | Mass estimate of the clump | |
MASS_SIG | real*8 | 1 | uncertainty on the mass estimate of the clump|
MASS_LOW[1,2,3] | real*8 | Lower 68%, 95% and 99% confidence limit of the mass estimate | |
MASS_UP[1,2,3] | real*8 | Upper 68%, 95% and 99% confidence limit of the mass estimate | |
DENSITY | real*8 | cm-3 | Mean density of the clump |
DENSITY_SIG | real*8 | cm-3 | 1 | uncertainty on the mean density estimate of the clump
DENSITY_LOW[1,2,3] | real*8 | cm-3 | Lower 68%, 95% and 99% confidence limit of the mean density estimate |
DENSITY_UP[1,2,3] | real*8 | cm-3 | Upper 68%, 95% and 99% confidence limit of the mean density estimate |
SIZE | real*8 | pc | Physical size of the clump |
SIZE_SIG | real*8 | pc | 1 | uncertainty on the physical size estimate of the clump
SIZE_LOW[1,2,3] | real*8 | pc | Lower 68%, 95% and 99% confidence limit of the physical size estimate |
SIZE_UP[1,2,3] | real*8 | pc | Upper 68%, 95% and 99% confidence limit of the physical size estimate |
LUMINOSITY | real*8 | Lo | Luminosity of the clump |
LUMINOSITY_SIG | real*8 | Lo | 1 | uncertainty on the luminosity estimate of the clump
LUMINOSITY_LOW[1,2,3] | real*8 | Lo | Lower 68%, 95% and 99% confidence limit of the luminosity estimate |
LUMINOSITY_UP[1,2,3] | real*8 | Lo | Upper 68%, 95% and 99% confidence limit of the luminosity estimate |
Flags | |||
FITS Keyword | Data Type | Units | Description |
XFLAG_LMC | int*4 | 0/1 | 1 if part of the LMC |
XFLAG_SMC | int*4 | 0/1 | 1 if part of the SMC |
XFLAG_ECC | int*4 | 0/1 | 1 if present in the ECC |
XFLAG_PCCS_857 | int*4 | 0/1 | 1 if present in the PCCS 857 GHz band |
XFLAG_PCCS_545 | int*4 | 0/1 | 1 if present in the PCCS 545 GHz band |
XFLAG_PCCS_353 | int*4 | 0/1 | 1 if present in the PCCS 353 GHz band |
XFLAG_PCCS_217 | int*4 | 0/1 | 1 if present in the PCCS 217 GHz band |
XFLAG_PCCS_143 | int*4 | 0/1 | 1 if present in the PCCS 143 GHz band |
XFLAG_PCCS_100 | int*4 | 0/1 | 1 if present in the PCCS 100 GHz band |
XFLAG_PCCS_70 | int*4 | 0/1 | 1 if present in the PCCS 70 GHz band |
XFLAG_PCCS_44 | int*4 | 0/1 | 1 if present in the PCCS 44 GHz band |
XFLAG_PCCS_30 | int*4 | 0/1 | 1 if present in the PCCS 30 GHz band |
XFLAG_PSZ | int*4 | 0/1 | 1 if present in the PCCS PSZ |
XFLAG_PHZ | int*4 | 0/1 | 1 if present in the PCCS HZ |
XFLAG_HKP_GCC | int*4 | 0/1 | 1 if present in the Herschel HKP-GCC |
References[edit]
- ↑ 1.01.1 Planck 2015 results. XXVII. The second Planck catalogue of Sunyaev-Zeldovich sources, Planck Collaboration, 2016, A&A, 594, A27.
- ↑ 2.02.12.2 Planck 2013 results. XXIX. The Planck Catalogue of Sunyaev-Zeldovich sources, Planck Collaboration, 2014, A&A, 571, A29.
- ↑ The MCXC: a meta-catalogue of x-ray detected clusters of galaxies, R. Piffaretti, M. Arnaud, G. W. Pratt, E. Pointecouteau, J.-B. Melin, A&A, 534, A109, (2011).
- ↑ A Catalog of 132,684 Clusters of Galaxies Identified from Sloan Digital Sky Survey III, Z. L. Wen, J. L. Han, F. S. Liu, ApJS, 199, 34, (2012).
- ↑ An Optical Catalog of Galaxy Clusters Obtained from an Adaptive Matched Filter Finder Applied to Sloan Digital Sky Survey Data Release 6, T. Szabo, E. Pierpaoli, F. Dong, A. Pipino, J. Gunn, ApJ, 736, 21, (2011).
- ↑ Galaxy Clusters Selected with the Sunyaev-Zel'dovich Effect from 2008 South Pole Telescope Observations, K. Vanderlinde, T. M. Crawford, T. de Haan, J. P. Dudley, L. Shaw, P. A. R. Ade, K. A. Aird, B. A. Benson, L. E. Bleem, M. Brodwin, J. E. Carlstrom, C. L. Chang, A. T. Crites, S. Desai, M. A. Dobbs, R. J. Foley, E. M. George, M. D. Gladders, N. R. Hall, N. W. Halverson, F. W. High, G. P. Holder, W. L. Holzapfel, J. D. Hrubes, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, A. Loehr, M. Lueker, D. P. Marrone, J. J. McMahon, J. Mehl, S. S. Meyer, J.J. Mohr, T. E. Montroy, C.-C. Ngeow, S. Padin, T. Plagge, C. Pryke, C. L. Reichardt, A. Rest, J. Ruel, J. E. Ruhl, K. K. Schaffer, E. Shirokoff, J. Song, H. G. Spieler, B. Stalder, Z. Staniszewski, A. A. Stark, C. W. Stubbs, A. van Engelen, J. D. Vieira, R. Williamson, Y. Yang, O. Zahn, A. Zenteno, ApJ, 722, 1180-1196, (2010).
- ↑ A Sunyaev-Zel'dovich-selected Sample of the Most Massive Galaxy Clusters in the 2500 deg$^{2}$ South Pole Telescope Survey, R. Williamson, B. A. Benson, F. W. High, K. Vanderlinde, P. A. R. Ade, K. A. Aird, K. Andersson, R. Armstrong, M. L. N. Ashby, M. Bautz, G. Bazin, E. Bertin, L. E. Bleem, M. Bonamente, M. Brodwin, J. E. Carlstrom, C. L. Chang, S. C. Chapman, A. Clocchiatti, T. M. Crawford, A. T. Crites, T. de Haan, S. Desai, M. A. Dobbs, J. P. Dudley, G. G. Fazio, R. J. Foley, W. R. Forman, G. Garmire, E. M. George, M. D. Gladders, A. H. Gonzalez, N. W. Halverson, G. P. Holder, W. L. Holzapfel, S. Hoover, J. D. Hrubes, C. Jones, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, M. Lueker, D. Luong-Van, D. P. Marrone, J. J. McMahon, J. Mehl, S. S. Meyer, J. J. Mohr, T. E. Montroy, S. S. Murray, S. Padin, T. Plagge, C. Pryke, C. L. Reichardt, A. Rest, J. Ruel, J. E. Ruhl, B. R. Saliwanchik, A. Saro, K. K. Schaffer, L. Shaw, E. Shirokoff, J. Song, H. G. Spieler, B. Stalder, S. A. Stanford, Z. Staniszewski, A. A. Stark, K. Story, C. W. Stubbs, J. D. Vieira, A. Vikhlinin, A. Zenteno, ApJ, 738, 139, (2011).
- ↑ X-Ray Properties of the First Sunyaev-Zel'dovich Effect Selected Galaxy Cluster Sample from the South Pole Telescope, K. Andersson, B. A. Benson, P. A. R. Ade, K. A. Aird, B. Armstrong, M. Bautz, L. E. Bleem, M. Brodwin, J. E. Carlstrom, C. L. Chang, T. M. Crawford, A. T. Crites, T. de Haan, S. Desai, M. A. Dobbs, J. P. Dudley, R. J. Foley, W. R. Forman, G. Garmire, E. M. George, M. D. Gladders, N. W. Halverson, F. W. High, G. P. Holder, W. L. Holzapfel, J. D. Hrubes, C. Jones, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, M. Lueker, D. P. Marrone, J. J. McMahon, J. Mehl, S. S. Meyer, J. J. Mohr, T. E. Montroy, S. S. Murray, S. Padin, T. Plagge, C. Pryke, C. L. Reichardt, A. Rest, J. Ruel, J. E. Ruhl, K. K. Schaffer, L. Shaw, E. Shirokoff, J. Song, H. G. Spieler, B. Stalder, Z. Staniszewski, A. A. Stark, C. W. Stubbs, K. Vanderlinde, J. D. Vieira, A. Vikhlinin, R. Williamson, Y. Yang, O. Zahn, A. Zenteno, ApJ, 738, 48, (2011).
- ↑ Sunyaev-Zel'dovich Cluster Profiles Measured with the South Pole Telescope, T. Plagge, B. A. Benson, P. A. R. Ade, K. A. Aird, L. E. Bleem, J. E. Carlstrom, C. L. Chang, H.-M. Cho, T. M. Crawford, A. T. Crites, T. de Haan, M. A. Dobbs, E. M. George, N. R. Hall, N. W. Halverson, G. P. Holder, W. L. Holzapfel, J. D. Hrubes, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, M. Lueker, D. Marrone, J. J. McMahon, J. Mehl, S. S. Meyer, J. J. Mohr, T. E. Montroy, S. Padin, C. Pryke, C. L. Reichardt, J. E. Ruhl, K. K. Schaffer, L. Shaw, E. Shirokoff, H. G. Spieler, B. Stalder, Z. Staniszewski, A. A. Stark, K. Vanderlinde, J. D. Vieira, R. Williamson, O. Zahn, ApJ, 716, 1118-1135, (2010).
- ↑ Galaxy Clusters Discovered via the Sunyaev-Zel'dovich Effect in the First 720 Square Degrees of the South Pole Telescope Survey, C. L. Reichardt, B. Stalder, L. E. Bleem, T. E. Montroy, K. A. Aird, K. Andersson, R. Armstrong, M. L. N. Ashby, M. Bautz, M. Bayliss, G. Bazin, B. A. Benson, M. Brodwin, J. E. Carlstrom, C. L. Chang, H. M. Cho, A. Clocchiatti, T. M. Crawford, A. T. Crites, T. de Haan, S. Desai, M. A. Dobbs, J. P. Dudley, R. J. Foley, W. R. Forman, E. M. George, M. D. Gladders, A. H. Gonzalez, N. W. Halverson, N. L. Harrington, F. W. High, G. P. Holder, W. L. Holzapfel, S. Hoover, J. D. Hrubes, C. Jones, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, J. Liu, M. Lueker, D. Luong-Van, A. Mantz, D. P. Marrone, M. McDonald, J. J. McMahon, J. Mehl, S. S. Meyer, L. Mocanu, J. J. Mohr, S. S. Murray, T. Natoli, S. Padin, T. Plagge, C. Pryke, A. Rest, J. Ruel, J. E. Ruhl, B. R. Saliwanchik, A. Saro, J. T. Sayre, K. K. Schaffer, L. Shaw, E. Shirokoff, J. Song, H. G. Spieler, Z. Staniszewski, A. A. Stark, K. Story, C. W. Stubbs, R. Suhada, A. van Engelen, K. Vanderlinde, J. D. Vieira, A. Vikhlinin, R. Williamson, O. Zahn, A. Zenteno, ApJ, 763, 127, (2013).
- ↑ South Pole Telescope Detections of the Previously Unconfirmed Planck Early Sunyaev-Zel'dovich Clusters in the Southern Hemisphere, K. Story, K. A. Aird, K. Andersson, R. Armstrong, G. Bazin, B. A. Benson, L. E. Bleem, M. Bonamente, M. Brodwin, J. E. Carlstrom, C. L. Chang, A. Clocchiatti, T. M. Crawford, A. T. Crites, T. de Haan, S. Desai, M. A. Dobbs, J. P. Dudley, R. J. Foley, E. M. George, M. D. Gladders, A. H. Gonzalez, N. W. Halverson, F. W. High, G. P. Holder, W. L. Holzapfel, S. Hoover, J. D. Hrubes, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, M. Lueker, D. Luong-Van, D. P. Marrone, J. J. McMahon, J. Mehl, S. S. Meyer, J. J. Mohr, T. E. Montroy, S. Padin, T. Plagge, C. Pryke, C. L. Reichardt, A. Rest, J. Ruel, J. E. Ruhl, B. R. Saliwanchik, A. Saro, K. K. Schaffer, L. Shaw, E. Shirokoff, J. Song, H. G. Spieler, B. Stalder, Z. Staniszewski, A. A. Stark, C. W. Stubbs, K. Vanderlinde, J. D. Vieira, R. Williamson, A. Zenteno, ApJ, 735, L36, (2011).
- ↑ Redshifts, Sample Purity, and BCG Positions for the Galaxy Cluster Catalog from the First 720 Square Degrees of the South Pole Telescope Survey, J. Song, A. Zenteno, B. Stalder, S. Desai, L. E. Bleem, K. A. Aird, R. Armstrong, M. L. N. Ashby, M. Bayliss, G. Bazin, B. A. Benson, E. Bertin, M. Brodwin, J. E. Carlstrom, C. L. Chang, H. M. Cho, A. Clocchiatti, T. M. Crawford, A. T. Crites, T. de Haan, M. A. Dobbs, J. P. Dudley, R. J. Foley, E. M. George, D. Gettings, M. D. Gladders, A. H. Gonzalez, N. W. Halverson, N. L. Harrington, F. W. High, G. P. Holder, W. L. Holzapfel, S. Hoover, J. D. Hrubes, M. Joy, R. Keisler, L. Knox, A. T. Lee, E. M. Leitch, J. Liu, M. Lueker, D. Luong-Van, D. P. Marrone, M. McDonald, J. J. McMahon, J. Mehl, S. S. Meyer, L. Mocanu, J. J. Mohr, T. E. Montroy, T. Natoli, D. Nurgaliev, S. Padin, T. Plagge, C. Pryke, C. L. Reichardt, A. Rest, J. Ruel, J. E. Ruhl, B. R. Saliwanchik, A. Saro, J. T. Sayre, K. K. Schaffer, L. Shaw, E. Shirokoff, R. Suhada, H. G. Spieler, S. A. Stanford, Z. Staniszewski, A. A. Stark, K. Story, C. W. Stubbs, A. van Engelen, K. Vanderlinde, J. D. Vieira, R. Williamson, O. Zahn, ApJ, 761, 22, (2012).
- ↑ The Atacama Cosmology Telescope: Sunyaev-Zel'dovich selected galaxy clusters at 148 GHz from three seasons of data, M. Hasselfield, M. Hilton, T. A. Marriage, G. E. Addison, L. F. Barrientos, N. Battaglia, E. S. Battistelli, J. R. Bond, D. Crichton, S. Das, M. J. Devlin, S. R. Dicker, J. Dunkley, R. Dünner, J. W. Fowler, M. B. Gralla, A. Hajian, M. Halpern, A. D. Hincks, R. Hlozek, J. P. Hughes, L. Infante, K. D. Irwin, A. Kosowsky, D. Marsden, F. Menanteau, K. Moodley, M. D. Niemack, M. R. Nolta, L. A. Page, B. Partridge, E. D. Reese, B. L. Schmitt, N. Sehgal, B. D. Sherwin, J. Sievers, C. Sifóon, D. N. Spergel, S. T. Staggs, D. S. Swetz, E. R. Switzer, R. Thornton, H. Trac, E. J. Wollack, J. Cosmology Astropart. Phys., 7, 8, (2013).
- ↑ The Atacama Cosmology Telescope: Sunyaev-Zel'dovich-Selected Galaxy Clusters at 148 GHz in the 2008 Survey, T. A. Marriage, V. Acquaviva, P. A. R. Ade, P. Aguirre, M. Amiri, J. W. Appel, L. F. Barrientos, E. S. Battistelli, J. R. Bond, B. Brown, B. Burger, J. Chervenak, S. Das, M. J. Devlin, S. R. Dicker, W. Bertrand Doriese, J. Dunkley, R. Dünner, T. Essinger-Hileman, R. P. Fisher, J. W. Fowler, A. Hajian, M. Halpern, M. Hasselfield, C. Hernández-Monteagudo, G. C. Hilton, M. Hilton, A. D. Hincks, R. Hlozek, K. M. Huffenberger, D. Handel Hughes, J. P. Hughes, L. Infante, K. D. Irwin, J. Baptiste Juin, M. Kaul, J. Klein, A. Kosowsky, J. M. Lau, M. Limon, Y.-T. Lin, R. H. Lupton, D. Marsden, K. Martocci, P. Mauskopf, F. Menanteau, K. Moodley, H. Moseley, C. B. Netterfield, M. D. Niemack, M. R. Nolta, L. A. Page, L. Parker, B. Partridge, H. Quintana, E. D. Reese, B. Reid, N. Sehgal, B. D. Sherwin, J. Sievers, D. N. Spergel, S. T. Staggs, D. S. Swetz, E. R. Switzer, R. Thornton, H. Trac, C. Tucker, R. Warne, G. Wilson, E. Wollack, Y. Zhao, ApJ, 737, 61, (2011).
- ↑ The Atacama Cosmology Telescope: Physical Properties and Purity of a Galaxy Cluster Sample Selected via the Sunyaev-Zel'dovich Effect, F. Menanteau, J. González, J.-B. Juin, T. A. Marriage, E. D. Reese, V. Acquaviva, P. Aguirre, J. W. Appel, A. J. Baker, L. F. Barrientos, E. S. Battistelli, J. R. Bond, S. Das, A. J. Deshpande, M. J. Devlin, S. Dicker, J. Dunkley, R. Dünner, T. Essinger-Hileman, J. W. Fowler, A. Hajian, M. Halpern, M. Hasselfield, C. Hernández-Monteagudo, M. Hilton, A. D. Hincks, R. Hlozek, K. M. Huffenberger, J. P. Hughes, L. Infante, K. D. Irwin, J. Klein, A. Kosowsky, Y.-T. Lin, D. Marsden, K. Moodley, M. D. Niemack, M. R. Nolta, L. A. Page, L. Parker, B. Partridge, N. Sehgal, J. Sievers, D. N. Spergel, S. T. Staggs, D. Swetz, E. Switzer, R. Thornton, H. Trac, R. Warne, E. Wollack, Apj, 723, 1523-1541, (2010).
- ↑ The Atacama Cosmology Telescope: Dynamical Masses and Scaling Relations for a Sample of Massive Sunyaev-Zel'dovich Effect Selected Galaxy Clusters, C. Sifón, F. Menanteau, M. Hasselfield, T. A. Marriage, J. P. Hughes, L. F. Barrientos, J. González, L. Infante, G. E. Addison, A. J. Baker, N. Battaglia, J. R. Bond, D. Crichton, S. Das, M. J. Devlin, J. Dunkley, R. Dünner, M. B. Gralla, A. Hajian, M. Hilton, A. D. Hincks, A. B. Kosowsky, D. Marsden, K. Moodley, M. D. Niemack, M. R. Nolta, L. A. Page, B. Partridge, E. D. Reese, N. Sehgal, J. Sievers, D. N. Spergel, S. T. Staggs, R. J. Thornton, H. Trac, E. J. Wollack, ApJ, 772, 25, (2013).
- ↑ 17.017.1 Planck 2015 results. XXVIII. The Planck catalogue of Galactic cold clumps, Planck Collaboration, 2016, A&A, 594, A28.
- ↑
(Planck) Low Frequency Instrument
(Planck) High Frequency Instrument
Flexible Image Transfer Specification
Data Processing Center
Full-Width-at-Half-Maximum
Early Release Compact Source Catalog
(Hierarchical Equal Area isoLatitude Pixelation of a sphere, <ref name="Template:Gorski2005">HEALPix: A Framework for High-Resolution Discretization and Fast Analysis of Data Distributed on the Sphere, K. M. Górski, E. Hivon, A. J. Banday, B. D. Wandelt, F. K. Hansen, M. Reinecke, M. Bartelmann, ApJ, 622, 759-771, (2005).
Sunyaev-Zel'dovich