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XMMSTACK - XMM-Newton Serendipitous Source Catalog: 5XMM-DR15 Full (Stacked) Catalog |
HEASARC Archive |
Overview
The XMMSTACK table contains the complete Fifth XMM-Newton Serendipitous Source Catalog. The 5XMM-DR15 is the fifth generation catalog of serendipitous X-ray sources from the European Space Agency's (ESA) XMM-Newton observatory, and has been created by the XMM-Newton Survey Science Center (SSC) in collaboration with the XMM-Newton Science Operations Center (SOC) on behalf of ESA. For this fifth generation of catalogs, only a stacked catalog of sources (with the individual detections and upper limits) is provided. This stacked catalog uses improved stacking methodology which allows all the individual observations to be included, contrary to stacked versions prior to 5XMM-DR15.The catalog contains source detections drawn from a total of 14,616 XMM-Newton EPIC observations made between 2000 January 19 and 2024 October 14; all datasets included were publicly available by 2024 October 31 but not all public observations are included in this catalog. This is due to some observations having very poor signal to noise or processing issues. The net area of the catalog fields taking account of the substantial overlaps between observations is ~1397 deg2.
5XMM-DR15 contains 818,656 unique X-ray sources and 2,578,752 X-ray detections or upper limits above the processing likelihood threshold (column STACK_DET_ML) of 6. Almost half of all sources (411,307) have more than one detection in the catalog (up to 98 repeat observations in the most extreme case).
The catalog distinguishes between extended emission and point-like detections. Parameters of detections of extended sources are only reliable up to the maximum extent measure of 80 arcseconds. There are 42,669 detections of extended emission, only about half of the number in 4XMM-DR14, but twice the number of 'clean' extended sources in 4XMM-DR14. This can be understood by the improved signal to noise in 5XMM-DR15 which is a stacked catalog, which ensures that extended sources are more reliably identified. Indeed more than 60% of the extended sources in 5XMM-DR15 (25,845) are identified as clean (SUM_FLAG < 3).
Due to intrinsic features of the instrumentation as well as some shortcomings of the source detection process, some detections are considered to be spurious or their parameters are considered to be unreliable. It is recommended to use a flag as filters to obtain what can be considered a 'clean' sample. There are 764,140 out of 818,656 sources that are considered to be clean (i.e., SUM_FLAG < 3).
For 408,694 detections, EPIC time series and 408,901 detections, EPIC spectra were automatically extracted during processing, and a chi2-variability test was applied to the time series. This is a significant increase since 4XMM-DR14 as these products are now extracted for detections with 50 EPIC counts, whereas 100 EPIC counts were previously required. 12,330 detections in the catalog are considered variable, within the timespan of the specific observation, at a probability of 10-5 or less based on the null-hypothesis that the source is constant. Of these, 10,907 have a SUM_FLAG < 3. On the long-term, 41,187 sources have a variability of a factor five or greater.
The median flux (in the total photon-energy band 0.2 - 12 keV) of the catalog detections is ~ 1.3 x 10-14 erg/cm2/s; in the soft energy band (0.2 - 2 keV) the median flux is ~ 2.9 x 10-15, and in the hard band (2 - 12 keV) it is ~7.6 x 10-15. The flux values from the three EPIC cameras are, overall, in agreement to ~10% for most energy bands. The median positional accuracy of the catalog point source detections is generally < 1.52 arcseconds (with a standard deviation of 1.41 arcseconds).
To maintain similar structure as prior to the 5XMM release, the HEASARC now provides the sources-only subset of 5XMM-DR15 as XMMSSC, which contains one row per unique source, for the 818,656 sources. This catalog, XMMSTACK, is the complete version of the catalog and has one row per source, followed by subsequent rows with information stemming from each detection or upper limit and thus has 3,397,248 rows. They both have the same number of columns (421). The catalog also contains a column with links to the IRAP catalog server summary pages. In the case of sources with multiple detections, the summary page of the best detection is selected (i.e., the detection with the largest exposure time, summed over all cameras), and the summary page gives cross-links to the other detections.
The energy bands used in the 5XMM-DR15 processing were the same as for the 3XMM and 4XMM catalogs.
The following are the basic energy bands:
1 = 0.2 - 0.5 keV 2 = 0.5 - 1.0 keV 3 = 1.0 - 2.0 keV 4 = 2.0 - 4.5 keV 5 = 4.5 - 12.0 keV
while these are the broad energy bands:
6 = 0.2 - 2.0 keV soft band, no images made 7 = 2.0 - 12.0 keV hard band, no images made 8 = 0.2 - 12.0 keV total band
Catalog Bibcodes
2020A&A...641A.136W2016A&A...590A...1R
2009A&A...493..339W
Description
The 5XMM-DR15 catalog is the seventeenth publicly released XMM-Newton X-ray source catalog produced by the XMM-Newton Survey Science Center (SSC) consortium. It follows the 1XMM (released in April 2003), 2XMMp (July 2006), 2XMM (August 2007), 2XMMi (August 2008), 2XMMi-DR3 (April 2010), 3XMM-DR4 (July 2013), 3XMM-DR5 (April 2015), 3XMM-DR6 (July 2016), 3XMM-DR7 (June 2017), 3XMM-DR8 (May 2018), 4XMM-DR9 (December 2019), 4XMM-DR10 (December 2020), 4XMM-DR11 (August 2021), 4XMM-DR12 (July 2022), 4XMM-DR13 (July 2023), and 4XMM-DR14 (July 2024) catalogs. 2XMMp was a preliminary version of 2XMM. 2XMMi and 2XMMi-DR3 were incremental versions of the 2XMM catalog.The 5XMM-DR15 catalog is about 18% larger than the 4XMM-DR14 catalog in terms of sources (126,547 more sources) and almost twice the number of sources in the stacked catalog, 4XMM-DR14s, as observations with no overlap were not considered in previous versions of the stacked catalog. In terms of the number of X-ray sources, it is 88% of the eROSITA DR1 catalog that covers half of the sky (Merloni et al. 2024) and more than twice the number of sources and detections that are in the Chandra source catalog version 2.1 (Evans et al. 2010). 5XMM-DR15 complements deeper Chandra and XMM-Newton small area surveys, probing a large sky area at the flux limit where the bulk of the objects that contribute to the X-ray background lie. The 5XMM-DR15 catalog provides a rich resource for generating large, well-defined samples for specific studies, utilizing the fact that X-ray selection is a highly efficient (arguably the most efficient) way of selecting certain types of object, notably active galaxies (AGN), clusters of galaxies, interacting compact binaries and active stellar coronae. The large sky area covered by the serendipitous survey, or equivalently the large size of the catalog, also means that 5XMM-DR15 is a superb resource for exploring the variety of the X-ray source population and identifying rare source types.
The production of the 5XMM-DR15 has been undertaken by the XMM-Newton SSC and XMM2ATHENA consortia in collaboration with the XMM-Newton Science Operations Center in fulfillment of one of its major responsibilities within the XMM-Newton project. The catalog production process has been designed to fully exploit the capabilities of the XMM-Newton EPIC cameras and to ensure the integrity and quality of the resultant catalog through rigorous screening of the data.
5XMM-DR15 is based on the pipeline configurations 21.51. This pipeline version contains many changes with respect to the pipeline used to make the previous major version of the catalog, 4XMM. The main changes to the EPIC processing include an empirical correction the MOS effective area to align with the pn effective area, along with a correction to the pn effective area above 3.0 keV to align EPIC pn to NuSTAR, which has the advantage of carrying out calibration without the mirror module and is therefore more accurate, an update to the CCD layout in the LINCOORD current calibration file (CCF) to align the source positions with the pn camera source positions (see Webb, Traulsen et al. 2026), introducing an evolving Energy Conversion Factor (ECF) with time for the MOS cameras, extracting spectra and lightcurves for each detection when there are more than 50 EPIC counts (previously 100 EPIC counts were required), and new source detection techniques developed for stacked source detection, which involves first fitting the position, extent and common flux and spectral parameters to each detection using the ECF in spectral fitting before maximum likelihood fitting and determining the final source parameters and extracting the variability information through point spread function (PSF) photometry for each detection. More information on these changes can be found in Webb, Traulsen et al., (2026), currently the draft version available.
As in previous versions of the stacked catalog, the SRCID is not propagated from previous versions.
References
If you use the catalogs 5XMM-DR15 for your research and publish the results, please use the acknowledgment below and cite the relevant paper as either of the following:
Webb et al. (2020), "The XMM-Newton serendipitous survey. XI. The fifth
XMM-Newton serendipitous source catalogue", in prep (2026).
The following is the preferred citation of the 4XMM version of the catalog:
Webb et al. (2020), "The XMM-Newton serendipitous survey. IX. The fourth
XMM-Newton serendipitous source catalogue", <A&A, 641, 136 (2020)>
=2020A&A...641A.136W
Traulsen et al. (2020), "The XMM-Newton serendipitous survey. X: The
second source catalogue from overlapping XMM-Newton observations and its
long-term variable content", <A&A, 641, A137 (2020)>
=2020A&A...641A.137T
The following is the preferred citation of the 3XMM-DR8 version of the catalog:
Rosen, Webb, Watson et al. (2016), "The XMM-Newton Serendipitous Survey.
VII. The Third XMM-Newton Serendipitous Source Catalogue", A&A, 590, A1.
Should you use this catalog for your research and publish the results, the
authors request that you use the following acknowledgment:
"This research has made use of data obtained from the 5XMM serendipitous source catalog compiled by the XMM-Newton Survey Science Center, the XMM2ATHENA project and in collaboration with the XMM-Newton SOC."
Provenance
This database table was last updated by the HEASARC in June 2026. It contains the 5XMM-DR15 complete catalog, released by ESA on 2026-06-09 and obtained from the XMM-Newton Survey Science Center Consortium at http://xmmssc.irap.omp.eu/Catalogue/5XMM-DR15/5XMM_DR15.html. It is also available as a gzipped FITS file at https://heasarc.gsfc.nasa.gov/FTP/xmm/data/catalogues/5XMM_DR15cat_v1.0.fits.gz.The previous versions of the Serendipitous Source Catalog, 3XMM-DR5, 3XMM-DR6, 3XMM-DR7, 3XMM-DR8, 4XMM-DR9, 4XMM-DR10, 4XMM-DR11, 4XMM-DR12, 4XMM-DR13, and 4XMM-DR14 are also available in the same directory for comparison purposes as the files 3XMM_DR5cat_v1.0.fits.gz, 3XMM_DR6cat_v1.0.fits.gz, 3XMM_DR7cat_v1.0.fits.gz, 3XMM_DR8_cat_v1.0.fits.gz, 4XMM_DR9_cat_v1.0.fits.gz, 4XMM_DR10cat_v1.0.fits.gz, 4XMM_DR11cat_v1.0.fits.gz, 4XMM_DR12cat_v1.0.fits.gz, 4XMM_DR13cat_v1.0.fits.gz, and 4XMM_DR14cat_v1.0.fits.gz, respectively.
Catalog Properties
This section summarizes the main properties of the catalog but does not provide a detailed analysis. A comprehensive evaluation of the catalog is presented in the Webb, Traulsen et al., (2026) paper.Overview: The catalog contains source detections drawn from 14,616 XMM-Newton EPIC observations made between 2000 January 19 and 2024 October 14 and which were publicly available by 2024 November 30. Net exposure times in these observations range from < 1000 up to 2.7 million seconds. Figure 5.1 of the User Guide shows the distribution of fields on the sky.
The sky area of the catalog observations corrected for field overlaps is ~1,397 deg2.
The catalog contains 2,578,752 X-ray detections or upper limits with total-band (0.2 - 12 keV) likelihood values >= 6. These are detections of 818,656 unique X-ray sources, that is, 411,307 X-ray sources have multiple detections in separate observations (up to 98 observations). Of the 818,656 X-ray sources, 42,699 are classified as extended with 25,845 of these being in regions considered to be 'clean' (SUM_FLAG < 1).
Data Quality: As part of extensive quality evaluation for the catalog, each field has been visually screened. Regions where there were obvious deficiencies with the automatic source detection and parametrization process were identified and all detections within those regions were flagged (cf. 2XMM UG, Sec. 3.2.6 at http://xmmssc.irap.omp.eu/2XMM/UserGuide_xmmcat.html#CatVisScreen but importantly, note Section 3.11 at http://xmmssc.irap.omp.eu/3XMM-DR4/UserGuide_xmmcat.html#VisScreen). Such flagged detections include clearly spurious detections (many of which are classified as extended) as well as detections where the source parameters may be unreliable. For most uses of the catalog it is recommended to use SUM_FLAG as a filter to obtain what can be considered a 'clean' sample.
Note that no attempt is made to flag spurious detections arising from statistical fluctuations in the background.
Sensitivity and Photometry: Figure 5.2 presents, for each of the three cameras, the distributions of flux for energy bands 1 to 5 and also for the combined (EPIC) data. These give an indication of the limiting flux available in the catalogs for each of the bands.
Astrometry: Considerable improvements have been made to improve the astrometry for 5XMM and these are detailed in Webb, Traulsen et al., (2026), draft version available currently.
Products: Spectral Energy Distributions, Auxiliary stack data and source images are also available. More information about these data products is available from the User Guide.
Credits
The production of the 5XMM-DR15 catalog is a collaborative project involving the whole XMM-Newton SSC Consortium along with members of the XMM2ATHENA project:Institut de Recherche en Astrophysique et Planetologie, Toulouse, France Leibniz-Institut für Astrophysik, Potsdam (AIP), Germany Observatoire Astronomique de Strasbourg, France Département d'Astrophysique, CEA/DRF/IRFU, Saclay, France Instituto de Física de Cantabria, Santander, Spain University of Leicester, UK Mullard Space Science Laboratory, University College London, UK Max-Planck-Institut für extraterrestrische Physik, Germany IAASARS, National Observatory of Athens, I. Metaxa & V. Pavlou, 15236, Greece
The SSC team are grateful to the XMM-Newton SOC for their support in the catalog production activities.
This project has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement number 101004168, the XMM2ATHENA project.
The SSC acknowledges the use of the TOPCAT and STILTS software packages (written by Mark Taylor, University of Bristol) in the production and testing of the 5XMM-DR15 catalog.
Documentation
The User Guide for the 5XMM-DR15 Catalog, available at http://xmmssc.irap.omp.eu/Catalogue/5XMM-DR15/5XMM_DR15.html, contains details of the catalog production process and content. A complete description of this catalog and the parameters listed therein can be found there. The list of observations used in the catalog can be found at http://xmmssc.irap.omp.eu/Catalogue/5XMM-DR15/5xmmdr15_obslist.txt. The user should particularly refer to section 6 of the 5XMM-DR15 UG ("Known Problems and Other Issues") at http://xmmssc.irap.omp.eu/Catalogue/5XMM-DR15/5XMM-DR15_Catalogue_User_Guide.html#Problems as much of this material is not included in this HEASARC documentation.Key Changes in 5XMM-DR15 with Respect to Previous Versions
Data selection: XMM-Newton observations considered for inclusion in the 5XMM-DR15 catalog were those with ODFs available for processing up to 2024 October 14 and all were publicly available as of 2024 October 31. After allowing for a small number of observations which failed in processing for a variety of reasons, Table 2.1 gives the list of the final 14,616 observations which are included in the 5XMM-DR15 catalog.Data Processing: Data processing for the 5XMM-DR15 catalog was based on the SAS version 21 and carried out with the pipeline version 21.51 and the latest set of current calibration files at the time of processing (November and December 2024). This new version includes a number of improvements compared to previous versions. Improvements to the EPIC (and RGS) effective areas were made using an empirical correction from MOS to pn (and RGS to pn), as well as a further correction above 3 keV to align the pn to the NUSTAR spectral fits. A correction was also included to update the MOS CCD positions to improve the astrometry. The main data processing steps used to produce the 5XMM data products were similar to those outlined in (Webb et al. 2020, Rosen et al. 2016, Watson et al. 2009) and described on the SOC web pages. For all the 5XMM data, the observation data files were processed to produce calibrated event lists. The optimized background time intervals were identified and using them, the filtered exposures (taking into account exposure time, instrument mode, etc.), multi-energy-band X-ray images, and exposure maps were generated. The initial detections were made on single observations, using simultaneously all images and bands, one to five, from the three cameras when available, see Table 1. The probability, and corresponding likelihood, were computed from the null hypothesis that the measured counts in the search box result from a Poissonian fluctuation in the estimated background level. A detection mask was made for each camera that defines the area of the detector which is suitable for source detection. An initial source list was made using a 'box detection' algorithm. This slides a search box (20" x 20") across the image defined by the detection mask. Sources were cut-out using a radius that was dependent on source brightness in each band, and these areas of the image where sources had been detected were blanked out. The source-excised images, normalized by the exposure maps, and the corresponding masks are convolved with a Gaussian kernel to create the background map (Traulsen et al. 2019). A second box-source-detection pass was then carried out, creating a new source list, this time using the background maps ('map mode') which increased the source detection sensitivity compared to the first pass. The box size was again set to 20" x 20". A maximum likelihood fitting procedure was then applied to the sources to calculate source parameters in each input image, by fitting a model to the distribution of counts over a circular area of radius 60" (Watson et al. 2009). 1.19 million detections were made before the stacking procedure. These detections were then used to produce detection level spectra and lightcurves, if more than 50 EPIC counts per detection were detected, where previously 100 EPIC counts were required. This resulted in almost 409,000 spectra and lightcurves, an increase of 10% with respect to 4XMM-DR14. For the catalog of sources (5XMM-DR15), the exposures were stacked and source detection was carried out by first fitting the position, extent and common flux and spectral parameters to each detection using the ECF in spectral fitting before maximum likelihood fitting and determining the final source parameters and extracting the variability information through point spread function (PSF) photometry for each detection. Automatic and visual screening procedures were carried out to check for any problems in the data products.
Stacking and source detection: Source detection on XMM-Newton EPIC observations uses maximum-likelihood fits under Cash statistics as described for example by (Watson et al. 2009, Traulsen et al. 2019). With 5XMM, the authors introduced a revised approach to stacked source detection in order to handle all 5XMM data from single observations to 99 directly overlapping observations. During the source-detection step, the authors assumed that the flux of each source remains constant over all exposures and that its spectrum in the five standard energy bands can be described by a simple model. The authors chose an absorbed power law as the spectral model which is a reasonable approximation to most XMM-Newton sources (Watson et al. 2009). Under these assumptions, the equations of the maximum-likelihood detection take the same form and the same degrees of freedom irrespective of the number of exposures in which a source is fitted. The degrees of freedom are the source coordinates, the mean source flux, and the spectral parameters -- column density and power-law index -- if the source is fitted as point-like, and additionally the radius of the extent model, if the source is fitted as extended. The results of the five-band spectral fit in the detection step are given in the catalog in the columns with prefix "STACK_".
The photon flux is related to the measured count rates in each input image to source detection by energy conversion factors (ECFs). In the new XMM-Newton source detection, the ECFs for each fitted pair of spectral parameters, for each fitted detector position, and for each instrumental setup (EPIC/pn, MOS1, MOS2 with their respective filters) are extrapolated on the fly over a grid of pre-compiled values. They cover column densities between 1019-23 cm-2 and power-law indices between 0 and 5. Time-dependence of the EPIC instrumental cross-calibration is taken into account over six different epochs.
Once a source is reliably detected with a log-likelihood STACK_DET_ML >= 6, the assumptions of constant flux and power-law spectrum are dropped, and image-level count rates and related parameters are determined by forced PSF photometry at the detected source position and extent radius. During PSF photometry, the count rate in each contributing image is treated as a free fit parameter: the method used in source detection in the previous Serendipitous Source Catalogs from EPIC data. The photometry results are given in the catalog in the RATES, FLUX, DET_ML and related columns without the prefix STACK.
For each fit parameter, the lower and upper confidence limit are calculated, searching for the parameter values for which the minimum Cash statistics value plus one is reached. For an efficient and robust search, the source-detection task emldetect employs the so called false-position method, which is a numerical bracketing approach. If the calculation of an error component does not converge, this component is now set to undefined in all cases. Previously, a count-rate dependent fall-back value was used for coordinates, extent, and count rates. The total 1-sigma error on a parameter is the arithmetic mean of the lower and the upper error if both are defined. If one component does not converge, the other component is taken as the total error. In addition to the total errors, 5XMM also includes the asymmetric upper and lower errors on the image coordinates, the extent radius, and the spectral fit parameters STACK_FLUX, STACK_NH, and STACK_GAMMA.
Systematic position error: The systematic uncertainty of the 5XMM-DR15 astrometry is estimated using a statistical approach based on the cross-matching of the X-ray sources with an external catalog with accurate positions. The adopted methodology is similar to that described in Section 6.2 of Merloni et al. (2024). It is assumed that the X-ray positional errors are symmetric in the direction of the right ascension and declination and are described by the normal distribution. Under these assumptions the probability of a radial offset, r, of an X-ray source from its true position is given by the Rayleigh distribution with parameter sigma that represents the astrometric standard deviation in the right ascension or declination direction. The authors assumed that sigma has a statistical (sigmastat) and a systematic (sigmasys) component:
sigma = (sigmastat2 + sigmasys2)0.5
with sigmastat = RADEC_ERR/sqrt(2), i.e. the statistical error is
approximated by the RADEC_ERR parameter estimated by the detection chain.
The systematic uncertainty is inferred at the population level by modeling
the angular separation distribution between the positions of X-ray sources
and an external catalog with vanishing astrometric errors. The linear part
at large angular distances represents chance alignments and a pronounced peak
at small separations corresponds to true associations. Modeling the observed
number of pairs at a given angular separation can constrain the fraction of
X-ray sources with true associations in the external catalog, the sky
density of the external catalog, X-ray source positional uncertainty
and hence sigmasys2.
The total number of X-ray verses external catalog pairs at a given angular separation bin theta is a Poisson variate with expectation value Lambda(theta) = Nrand(theta) + N_assoctheta. Therefore the likelihood of the model can then be expressed as the product of the Poisson probabilities at each angular separation bin, see Webb, Traulsen et al. (2026)
The modeling assumes that the positional uncertainty of an X-ray source is given by Equation 1 and that the systematic uncertainty is the same for all sources. Although sigmasys depends on the number of X-ray photon counts of a source, this dependence is weak and therefore assuming a single catalog-wide value for this parameter is an acceptable approximation, see Webb, Traulsen et al. (2026). The external astrometric catalog used was quasars from Gaia and unWISE Data (Shu et al. 2019). The authors only considered Gaia/unWISE sources with probability of being a quasar >0.8 and g-band magnitude <20.5 mag. The latter criterion is adopted to minimize variations in the sky density of quasar candidates because of the variable depth of the Gaia survey as a result of the scanning law of the mission. The authors limited the 5XMM catalog to sources with emldetect detection likelihood EP_DET_ML>15 (to increase the purity of the sample), that are not spatially extended (parameter EXTENT=0), are not close to CCD gaps or the edges of the field of field of view (PN_MASKFRAC>0.9 or M1_MASKFRAC>0.9 or M2_MASKFRAC>0.9), have quality flags that do not indicate issues during the detection (SUM_FLAG=0) and lie outside the Galactic plane (Galactic latitude >30 degrees). For this sample, the authors inferred sigmasys = 0.88{pm}0.01 arcsec.
This sigmasys is larger than the one derived for 4XMM-DR10s by Traulsen et al. (2020), because the 5XMM data were not rectified astrometrically when producing DR15. The astrometric correction will be included in DR16 to further improve the source positions.
Long term variability: 5XMM-DR15 is a stacked catalog, containing all of the sources detected following the stacking of overlapping observations, but also includes the individual detections in each of the contributing observations and non-detections when no detection was made. This provides the user with long-term XMM-Newton variability over the 25 years of data used to construct the catalog. These data can be visualized in lightcurves produced for each source.
However, to increase the timeframe over which variability can be examined and to increase the number of data points for each source, the STONKS algorithm was implemented (Quintin et al. 2024). This algorithm uses a master catalog constructed from data from a variety of different observatories. To create the 5XMM-DR15 catalog, this master catalog was generated in February 2026 using the most recent versions of the XMM-Newton catalog (4XMM-DR14, Webb et al. 2020), Chandra Source Catalog version 2.1 (Evans et al. 2010), the Living Swift/XRT point-source catalog (Evans et al. 2023), the eROSITA eRASS1 catalog (Merloni et al. 2024), the XMM-Newton Slew survey catalog version 3, XMMSL3 (Saxton et a.l. 2008), the two ROSAT catalogs, 2RXS (Boller et al. 2016) and WGACAT (White et al. 1994). The authors also generated upper limits for the XMM-Newton non-detections using the RapidXMM (Ruiz et al. 2022) version of HILIGT (Saxton et al. 2022). Matching was done on a two by two basis using an algorithm based on (Budavary & Szalay 2008) and implemented in NWAY (Salvato et al. 2018), see Quintin et al. (2024) for the details of the algorithm. The authors ensured that the fluxes estimated were comparable by converting each flux detection to a single, common energy band. The common band the authors chose was the 0.1-12 keV band, as it contains the energy bands of every one of the missions the authors used and then assumed an absorbed power-law spectra, with parameters Gamma = 1.7 and NH = 3 x 1020 cm-2.
The pessimistic variability ratio was calculated, taking the ratio of the highest flux point minus the 1-sigma error and the lowest flux point plus the 1-sigma error. Alternatively, in the case of an upper limit, the difference is calculated using the 3-sigma upper limit and the highest flux point minus the 1-sigma error. The authors provided significant long-term variability for sources that have a ratio of five or greater. The variability is calculated for the detections made with the standard pipeline before stacking. This is provided in the column 'APPROX_SOURCE_VAR'. There are 41,187 detections with a variability ratio of five or greater, with the highest reaching a ratio of 78,000. The mean variability is a factor 80.
Spectral fitting: The procedure to select, merge and analyze the 5XMM spectra is similar to Viitanen et al 2025, with some changes in the procedure used to merge the spectra, and in the output quality flags. Standard PPS processing of individual observations includes spectral extraction for detections with more than 50 EPIC counts, with a corresponding background spectrum. For each of the stacked sources, the associated individual detections are checked for extracted spectra. Each spectrum is checked for a strictly positive number of total counts (in the extracted detection spectrum, including source and background), background counts (in the extracted background spectrum), and net counts (calculated by subtracting the background counts from the total counts, after scaling by the relative extraction areas), in the 0.2-12~keV band. If any of these conditions are not fulfilled, the spectrum is discarded from further processing.
The selected spectra are then separated by instrument (pn or MOS). Spectra from each instrument are merged. The procedure to decide which spectra to merge for each source has been simplified with respect to that in Viitanen et al 2025. The spectra are sorted in decreasing signal-to-noise ratio (defined as the net counts divided by twice the total counts minus the re-scaled background counts) and the cumulative signal-to-noise ratio of the spectra with higher or equal signal-to-noise ratio than the one under consideration is calculated. Spectra are only merged down to the point in which the maximum cumulative signal-to-noise ratio is reached. The merging is done using the SAS task epicspeccombine. The merged total and background spectra for each instrument are then re-binned to have one or more counts per bin. Spectral fitting and modeling were done with XSPEC (Arnaud 1996) through the Python interface together with the Bayesian X-ray Analysis (BXA) tool (Buchner et al 2014), which connects XSPEC to the nested-sampling package UltraNest (Buchner et al 2021). The spectral models were implemented in XSPEC and explored with BXA. To speed up the Bayesian fitting, the authors first performed a quick Levenberg-Marquardt fit to obtain approximate best-fit values, and then reduced the prior volume explored by UltraNest by centering the prior bounds on those preliminary estimates. For the power-law model used here, the prior range for NH was set to the preliminary best-fit value, clipped to the interval [0.001,10.0] (in units of 1022 cm-2), the prior range for Gamma was set to the preliminary best-fit value {pm}1.0, clipped to [1.0,3.0], and the prior range for log10(Flux) was set to the preliminary best-fit value {pm}2, clipped to [-15,-9]. This substantially reduced the prior volume explored by UltraNest and accelerated convergence. The posterior probability distributions were then obtained from the BXA/UltraNest sampling and stored as chains for further summary and export.
The spectra were fitted with an absorbed power law (in XSPEC notation cflux * phabs * zpowerlw) to the merged spectra. This model has three free spectral parameters: the flux (FLUX in the catalog, observed flux not corrected for absorption), the column density (NH, not constrained by the column density of our Galaxy in the direction of the source) and the spectral slope (GAMMA). In addition, when pn and MOS spectra are fitted jointly, the authors included an inter-instrument normalization parameter (IIN), implemented as a multiplicative constant, with the pn normalization fixed to unity and the MOS normalization left free. Future versions of the catalog will include spectral fitting with other models as well. All spectral fitting was performed using the Cash statistic (Cash 1979), which is appropriate for Poisson-distributed data and particularly effective in the low-count regime. Unfortunately, the Cash statistic does not provide a goodness-of-fit (GoF) indicator. This was estimated by fitting the merged background spectra with an empirical, camera-specific background model. The GoF was determined by re-binning the background spectra to have at least 20 counts per bin, and then the chi2 of the best fit Cash model was compared to the expected value for an equivalent number of degrees of freedom (see Viitanen et al 2025). Fits with probabilities p<0.01 were discarded and excluded from further analysis. The second step, for the merged spectra whose corresponding background spectra passed the previous filter, was fitting the pn and MOS spectra using a combined source+background model, in which all background-shape parameters were fixed to the best-fit values obtained in the initial background-only fit, leaving only the background normalization free to vary. This approach ensures consistency and mitigates overfitting. The method of Buchner et al 2014 was used to estimate the GoF of the source+background fits. The p-values were estimated using a permutation test. For each source, the authors generated 1,000 resampled datasets by randomly redistributing the combined data+model counts into two equal-size subsamples, allowing each energy-bin count to originate from either the observed or modeled spectrum. For each resampling, the authors computed the corresponding Kolmogorov-Smirnov (KS) statistic. The p-value was then defined as the fraction of permutations yielding a KS statistic larger than that of the original data-model comparison. Models with KS p-values >=0.01 were considered acceptable fits.
Catalog values provided include the median and the 5 and 95% percentiles, degrees of freedom and the KS GoF p-value (PVALUE) of the source+background fit. The INFO parameter links to the list of spectra included in the merged spectrum (designated by their observation identification OBS_ID and source number (SRCNUM). A flag (FLAG) is provided, with the following possible values:
0 : no issues detected 1 : zero or negative source counts 2 : zero or negative source counts (also implies <=0 net counts) 3 : could not create merged spectrum 4 : source+background or background fit failed 5 : poor goodness-of-fit, with KS p-value <0.01 (or pre-fit p-value <0.01 if KS is unavailable) 6 : photon index pegged, with PhoIndex median within 0.05 of the hard prior limits <= 1.05 or >= 2.95, for priors in the range [1.0,3.0]) 7 : poor goodness-of-fit and photon index pegged 8 : NH pegged, with median NH >= 9.5 (near the upper cap of 10.0, in units of 1022 cm-2) 9 : poor goodness-of-fit and NH pegged 10 : photon index pegged and NH pegged 11 : poor goodness-of-fit, photon index pegged, and NH pegged
Optical monitor products: The XMM-OM observes the sky simultaneously with the X-ray instruments onboard XMM-Newton. For 5XMM, XMM-OM counterparts to X-ray sources are drawn from version 6.2 of the XMM-Newton Serendipitous Ultraviolet Source Survey (XMM-SUSS) catalog (Page et al. 2012). The XMM-SUSS is compiled from images obtained through the six primary photometric filters of XMM-OM, which have effective wavelengths from 2120 Angstrom (UVW2) to 5430 Angstrom (V). XMM-SUSS 6.2 includes sources detected in any of the six optical and ultraviolet photometric filters.
For XMM-OM counterparts, 5XMM contains the corresponding source ID in XMM-SUSS 6.2, the match-probability to the X-ray source (using an NWAY-like algorithm, Salvato et al. 2018) and the following information for each and every XMM-OM passband in which the counterpart is detected: AB magnitude and magnitude uncertainty, a quality flag, an extended flag, a chi2 value and the degrees of freedom for which it is calculated. The AB magnitude and uncertainty provided for each band is a weighted mean of the measurements over all XMM-Newton observations in which the source is detected, and the corresponding magnitude uncertainty. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. These flags are :
The meaning of the quality flags (columns OM_filter_QUALITY_FLAG) in 5XMM are as follows:
bit 0 (value 1) source on a bad pixel bit 1 (value 2) source on a readout streak bit 2 (value 4) source on a smoke-ring bit 3 (value 8) source on a diffraction spike bit 4 (value 16) source affected by Mod-8 pattern bit 5 (value 32) source within the central enhancement bit 6 (value 64) source near a bright source bit 7 (value 128) source near the edge bit 8 (value 256) point source within an extended source bit 9 (value 512) weird source (bright pixel) bit 10 (value 1,024) multiple exposure values within photometry aperture bit 11 (value 2,048) the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) the source is too bright (rate > 0.97 c/frame)
The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the corresponding band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. Where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS 6.2. Caution is advised in inferring variability from chi2 when the corresponding quality flag is other than 0, or for sources which appear point-like in some XMM-Newton observations and extended in others, because the photometry is measured differently for extended and point-like sources (see Page et al. 2012). XMM-OM counterparts have been classified probabilistically into Galactic and extragalactic source types and this classification information is included in 5XMM; see Section Classification for more details.
Redshifts: Photometric redshifts (photo-z) were calculated by selecting all 5XMM sources classified as AGN (see Section Classification) and outside the galactic plane (|b| > 20 degrees). The authors used the optical and NIR-MIR photometry provided in their SEDs (Section Products) and calculated photometric redshifts for these sources. The authors used two different algorithms for estimating redshifts: TPZ, a machine learning algorithm (Carrasco Kind & Brunner, 2013) using the training sample described below MLZ-TPZ is a machine learning algorithm based on a supervised technique with prediction trees and random forest. The photometric redshifts and the corresponding cross-validation of the results was done through the photo-z pipeline developed for 5XMM, which includes a k-fold cross-validation method for evaluating the accuracy and reliability of our method, the selection of the optimal feature set for photo-z calculations using a Recursive Elimination Feature algorithm, and the quality evaluation of the individual photo-z, by using the shape of the redshift probability distribution given by TPZ. The authors also used the LePhare algorithm, a template fitting algorithm (Arnouts et al. 1999, Ilbert et al. 2006), an SED template fitting code, well adapted to find high-redshift sources that would be otherwise missed by TPZ, since the results of machine learning methods are limited to the redshift range of the corresponding training sample (redshifts below 3.5 in our case). Moreover, LePhare allows us to estimate redshifts for sources with only partial photometry in the optical or infrared bands. The authors used two different sets of templates for LePhare, depending on the optical morphological classification of the sources. For extended objects the authors used the templates proposed by Salvato et al. 2009, 2011 for the COSMOS survey. For point-like objects the authors used the eFEDS templates (Salvato et al. 2022).
The authors compiled a large spectroscopic sample of X-ray selected extragalactic sources that can be used for the training and cross-validation of the machine learning and template fitting algorithms the authors used for calculating photometric redshifts. The training sample was selected from the second version of the Millions of Optical-Radio/X-ray Associations (MORX) Catalog (Flesch 2024). The authors selected sources with secure spectroscopic redshifts, with an X-ray counterpart and classified as AGN or galaxies. The authors defined four different subsamples based on the photometry available in these large area optical surveys: SDSS sample (~55,000 sources), PanSTARRS sample (~47,000 sources), SkyMapper sample (~6,000 sources), and DES sample (~14,000 sources). Ancillary photometry in the near- (from the 2MASS, UKIDSS and VHS surveys) and mid-infrared (AllWISE catalog) was included if available.
This training sample is an order of magnitude larger than those previously used in similar efforts for estimating photometric redshifts for X-ray sources using machine learning techniques (e.g. Mountrichas et al. 2017, Ruiz et al. 2018). A variety of validation techniques for the photometric redshifts were carried out (see Webb, Traulsen et al. 2026 for more details). The spectral redshifts are provided in the 5XMM catalog under the column REDSHIFT_ZSP. 31,831 spectral redshifts are provided in 5XMM-DR15 and 154,734 photometric redshifts (REDSHIFT_TPZ_Z_BEST and REDSHIFT_LPH_Z_BEST, along with the confidence limits on these redshifts and a link to further information on distance determination per source).
Classification: Both the X-ray sources and the optical/ultraviolet sources in XMM-SUSS 6.2 have undergone a classification using an adapted version of the Naive Bayes classifier CLAXBOI (Tranin et al. 2022). For the X-ray sources this algorithm uses the XMM-Newton X-ray properties of each source such as the hardness ratios, spectral fits (with a power law, but also an APEC model), along with the X-ray to r-band flux ratio, the X-ray to W1 infra-red band ratio when these complementary data are available, the maximum X-ray variability, the X-ray luminosity when the distance is known from Gaia or the Glade+ catalog (Dálya et al. 2022) and the distance to the center of the galaxy in case of extra-galactic sources associated with a galaxy. For the X-ray sources, the most-likely classifications are given in the column CLASSX_CLASS. These are AGN, star, Galactic X-ray binary, cataclysmic variable, background AGN, extra-galactic X-ray binary and extended sources. The authors also provided an outlier classification, for the case when none of the above source-types matches the source. Seven further columns provide the probability attributed to each classification. This allows the user to make an informed decision about the reliability of the classification. For the X-ray sources, there are 556,337 AGN, 119,661 stars, 26,100 Galactic X-ray binaries, 1,276 cataclysmic variables, 49,969 background AGN, 22,732 extra-galactic X-ray binary and 42,581 extended sources. The higher the outlier value (maximum 10), the more likely the source does not fit any of the designated categories, but see also Tranin et al. (2022). 49,404 sources have an outlier value greater than five, 3,943 have the best classification as AGN, 17,834 have the best classification as a star, 15,554 as a Galactic X-ray binary, 3,657 as extra-galactic X-ray binaries and 2,394 as extended sources. This could imply that these are extreme types of each classification, or indeed, different objects.
For the XMM-OM sources only three source classes were retained, quasar (QSO), galaxies and stars. The most probable classification is given in the 'CLASSOPT_CLASS' column. Again the probability attributed to the three classes for each source is provided in the three subsequent columns. A total of 201,536 sources have an optical classification. There are 66,306 QSO, 29,971 galaxies and 105,259 stars. Of the 20,564 sources with both an X-ray classification of star and an XMM-OM classification, all of the sources are classified as stars, implying that the classification is reliable. The other classifications are more complicated to compare as an AGN does not necessarily have the same definition as a quasar, however, of the X-ray sources classified as an AGN and with an XMM-OM classification, two-thirds are classified as a quasar.
Hot areas in the detector plane: Warm pixels on a CCD (at a few counts per exposure) are too faint to be detected as such by the automatic processing, but can either push faint sources above detection level, or create spurious sources when combined with statistical fluctuations. This is an intrinsically random process, not visible over a short period of time, but which creates hot areas when projecting all sources detected over 24 years onto the detector plane.
The authors addressed this by projecting all sources onto CCD coordinates PN/M1/M2_RAWX/Y, keeping only sources above the detection threshold with the current instrument alone. In that way, the authors could distinguish hot areas coming from different instruments. The authors proceeded to detect hot pixels or columns in each CCD, using a similar method to the SAS task embadpixfind. For more information see Webb et al. (2020). Many of the warm pixels were not present at the beginning of the mission, and some appear for a short amount of time. So the authors tested each hot area for variability using revolution number, and the same Kolmogorov-Smirnov-based algorithm used to detect segments of bright columns, compared to the reference established over all sources on all CCDs and all instruments. This resulted in a revolution interval for each hot area.
Sources on a hot area for a particular instrument and within the corresponding revolution interval are flagged with flag 10 (PN_FLAG, M1_FLAG or M2_FLAG) as T (true) and then propagated to the SUM_FLAG to indicate a possibly spurious detection/source). In version 5XMM-DR15 this flagging was done after source detection, but from versions DR16, this step will be carried out before the stacked source detection. Below, the authors provided the quality flags in 5XMM.
Table 3.1: Meaning of the characters in the quality flags PN_FLAG, M1_FLAG, M2_FLAG, EP_FLAG and their distribution in 5XMM-DR15.
Flag Description EP PN M1 M2 all 818,656 100% 753,847 100% 692,614 100% 777,900 100% 0 No warning issued 537,679 66% 550,693 73% 594,018 86% 679,272 87% 1 PSF coverage < 50% 160,445 20% 97,178 13% 42,025 6% 41,749 5% 2 Near a bright point-like source 4,090 0% 3,875 1% 3,588 1% 3,876 0% 3 Near a bright extended source 60,955 7% 56,180 7% 54,894 8% 58,519 8% 4 Extended near a bright point source 728 0% 683 0% 629 0% 675 0% 5 Extended near a bright extended source 12,201 1% 8,203 1% 9,917 1% 11,088 1% 6 Extended, significant in one band 6,146 1% 5,467 1% 5,644 1% 5,862 1% 7 Extended, flag 4, 5, or 6 14,605 2% 11,699 2% 12,654 2% 13,694 2% 8 On a bad pixel or CCD area 24,433 3% 24,342 3% 170 0% 34 0% 9 Near a bad CCD area 65,913 8% 65,711 9% 476 0% 268 0% 10 On a warm CCD pixel 13,662 2% 11 Flagged during visual screening 54,516 7%
Table 3.2: Meaning of the SUM_FLAG values:
Value Description 0 Good 1 if the warning flags EP_FLAG 1, 2, 3 or 9 set to true but not 7, 8, 10 or 11 2 if the possibly-spurious or warm pixel flags EP_FLAG 7, 8 or 10 set to true but not the manual flag 11 3 if the manual flag EP_FLAG 11 is set to true but not the spurious or warm pixel flags 7, 8 or 10 4 if the manual flag 11 as well as one of the spurious or warm pixel flags 7, 8 or 10 are set to trueThe default value of every flag is F for False. When a flag was set it means it has been changed to T for True.
The task dpssflag sets all flags except the camera-specific flags (i.e., flags 2,3,4,5,6,7) on the summary row (EPIC band 8) which are then propagated backwards to the individual cameras and bands.
User Guide for 5XMM
The extensive User Guide (UG) for the 2XMM catalog at http://xmmssc-www.star.le.ac.uk/Catalogue/2XMM/UserGuide_xmmcat.html still describes many of the details of the data processing and compilation approach applicable to the 5XMM-DR15 catalog. However, a significant number of changes to the processing have been implemented for 5XMM, and these are described in the 5XMM-DR15 documentationWatchouts
(1) The median statistical position error for the 5XMM-DR15 sources (RADEC_ERR/sqrt(2)) is 1.08", whereas for 4XMM-DR9 it was 0.8". This is because the astrometric correction carried out before stacking was not propagated to the final positions. This will be corrected in 5XMM-DR16.(2) For 5XMM-DR15 the identification of warm pixels (pixels that can become hot during a limited period of time) was carried out following the source detection on stacked data (indicated in the 10th detector flag, PN_FLAG, M1_FLAG or M2_FLAG) as T (true) and then propagated to the SUM_FLAG to indicate a possibly spurious detection/source. In versions from DR16, this step will be carried out before the stacked source detection.
Catalog Content and Organization
There are 421 parameters in the catalog. For each observation, there are up to three cameras with one or more exposures which were merged when the filter and sub-modes were the same (2XMM UG, Sec. 2.2 at http://xmmssc.irap.omp.eu/2XMM/UserGuide_xmmcat.html#SelExp). The data in each exposure are accumulated in several distinct energy bands (see Table 1 above). Camera-level measurements can further be combined into observation-level parameters. Consequently, the source parameters can refer to some or all of these levels: on the observation level there are the final mean parameters of the source (prefix 'EP'); on the camera level the data for each of the three cameras (where available) are given (prefix 'PN', 'M1', or 'M2'), and on the energy band level the energy-dependent details of the source parameters are given (indicated by a 'b' in the column name where b = 1, 2, 3, 4, 5, 8 or 9). Finally, on a meta-level, some parameters of sources that were detected more than once (prefix 'SC') were combined, see 2XMM UG, Sec. 3.2.4 at http://xmmssc.irap.omp.eu/2XMM/UserGuide_xmmcat.html#CatComb.It should be pointed out that the SAS used for the bulk reprocessing (for 5XMM) was from manifest pipeline version 21.51, which is based on SAS 21. A description of the column and possible cross-references follow below.
The following table gives an overview of the statistics of this catalog in comparison with 4XMM-DR14:
5XMM-DR15 4XMM-DR14 Increment
Number of observations 14,616 13,864 752
Observing interval 19-Jan-00 03-Feb-00 11 months
- 14-Oct-24 - 31-Nov-23
Sky coverage, taking overlaps 1,397 sq.deg 1,383 sq.deg 14 sq. deg
into account (>= 1ksec exposure)
Number of unique sources 818,656 692,109 126,547
Number of detections/upper limits 2,578,752 1,035,832 1,542,920
Number of 'clean' sources 764,140 585,899 179,241
(i.e., summary flag < 3)
Number of 'clean' (summary 25,845 22,147 3,698
flag < 3)
Number of detections with spectra 408,901 372,603 36,298
Number of detections with timeseries 408,694 372,313 36,381
Number of detections where the 12,330 8,380 3,950
probability of timeseries being
constant is < 1.0E-05
Known Problems and Other Issues
Please refer to http://xmmssc.irap.omp.eu/Catalogue/5XMM-DR15/5XMM_DR15.html#watchouts (the Watchouts section of the 5XMM-DR15 catalog page) for the latest information on 5XMM-DR15 catalog issues.Parameters
SrcID
A unique number assigned to a unique source determined through source
detection on the stack. The SRCID assignments in 5XMM bear no relation to
those in 4XMM.
Name
The IAU designation assigned to the unique SRCID. An IAU-style
identification, NAME, has been assigned to each unique source (SRCID) based
upon the IAU-registered classification, 4XMM, and the J2000.0 source
coordinates. The form of the IAU names is '4XMM Jhhmmss.sSddmmss' where
hhmmss.s is taken from the Right Ascension coordinate given in the RA
parameter and Sddmmss is the Declination taken from the Dec parameter.
ObsID
The XMM-Newton observation identification.
PPS_Srcnum
The decimal source number attributed to a detection by the automatic pipeline
processing. When expressed in hexadecimal, it identifies the SAS task
srcmatch source-specific product files belonging to this detection. (See
Appendix A.1 of the 2XMM UG at
http://xmmssc.irap.omp.eu/2XMM/UserGuide_xmmcat.html#AppProd
for more details).
N_Obs
The total number of observations per stack. The column value is set to null
in the observation-specific rows and can thus be used to select the summary
source rows per source, for example by the expression "N_OBS > 0".
N_Contrib
The number of contributing observations for which the source position is
inside the field of view. The column value is set to null in the
observation-specific rows and can thus be used to select the summary source
rows per source, for example by the expression "N_CONTRIB > 0".
N_Exp
The number of exposures, i.e. the number of active instruments, and is set in
each row of the catalog.
RA
The corrected Right Ascension of the detection in the selected equinox after
statistical correlation of the emldetect coordinates, RA_UNC and DEC_UNC,
with the USNO B1.0, 2MASS or SDSS (DR8) optical/IR source catalogs using the
SAS task catcorr (the process of correcting the coordinates is also referred
to as field rectification). In cases where the cross-correlation is
determined to be unreliable, no correction is applied and this value is
therefore the same as RA_UNC. The RA was given in J2000.0 decimal degrees in
the original table.
Dec
The corrected Declination of the detection in the selected equinox after
statistical correlation of the emldetect coordinates, RA_UNC and DEC_UNC,
with the USNO B1.0, 2MASS or SDSS (DR8) optical/IR source catalogs using the
SAS task catcorr (the process of correcting the coordinates is also referred
to as field rectification). In cases where the cross-correlation is
determined to be unreliable, no correction is applied and this value is
therefore the same as DEC_UNC. The Declination was given in J2000 decimal
degrees in the original table.
Error_Radius
The total positional uncertainty, computed as the sqrt(ra_err2 +
dec_err2) in arcseconds, where ra_err and dec_err are the uncertainties in
the RA and Dec coordinates, respectively.
Error_Ell_Major
The semi-major axis of the positional error ellipse, in arcseconds.
Error_Ell_Minor
The semi-minor axis of the positional error ellipse, in arcseconds.
Error_Ell_PA
The rotation angle of the positional error ellipse, in degrees.
LII
The corrected Galactic Longitude of the detection in degrees.
BII
The corrected Galactic Latitude of the detection in degrees.
X_Pixel
The image X coordinate in the image of the combined observation of a stack in their common coordinate system, called X_IMA in the original table, and based on the SAS task smldetect.
X_Pixel_Error
The symmetrical error on the X coordinate in the image of the combined observation of a stack in their common coordinate system, called X_IMA_ERR in original table and based on the SAS task emldetect.
X_Pixel_Neg_Err
The lower 1-sigma asymmetrical error on the X coordinate in the image of the combined observation of a stack in their common coordinate system, called X_IMA_ERR_LO in original table and based on the SAS task emldetect.
X_Pixel_Pos_Err
The upper 1-sigma asymmetrical error on the X coordinate in the image of the combined observation of a stack in their common coordinate system, called X_IMA_ERR_UP in original table and based on the SAS task emldetect.
Y_Pixel
The image Y coordinate in the image of the combined observation of a stack in their common coordinate system, called Y_IMA in the original table, and based on the SAS task smldetect.
Y_Pixel_Error
The symmetrical error on the Y coordinate in the image of the combined
observation of a stack in their common coordinate system, called Y_IMA_ERR in
original table and based on the SAS task emldetect.
Y_Pixel_Neg_Err
The lower 1-sigma asymmetrical error on the Y coordinate in the image of the
combined observation of a stack in their common coordinate system, called
Y_IMA_ERR_LO in original table and based on the SAS task emldetect.
Y_Pixel_Pos_Err
The upper 1-sigma asymmetrical error on the Y coordinate in the image of the
combined observation of a stack in their common coordinate system, called
Y_IMA_ERR_UP in original table and based on the SAS task emldetect.
Ccdpn
The PN CCD number in which the detection was made based on SAS task emldetect.
PN_RawX
Raw pixel position in the X direction of the PN detection, based on the SAS task emldetect.
PN_RawY
Raw pixel position in the Y direction of the PN detection, based on the SAS task emldetect.
Ccdm1
The MOS1 CCD number on which the detection was made, based on the SAS task emldetect.
M1_RawX
Raw pixel position in the X direction of the MOS1 detection, based on the SAS task emldetect.
M1_RawY
Raw pixel position in the Y direction of the MOS1 detection, based on the SAS task emldetect.
Ccdm2
The MOS2 CCD number on which the detection was made, based on the SAS task emldetect.
M2_RawX
Raw pixel position in the X direction of the MOS2 detection, based on the SAS task emldetect.
M2_RawY
Raw pixel position in the Y direction of the MOS2 detection, based on the SAS task emldetect.
Dist_NN
The distance to the nearest neighbor detection, in arcseconds; it is derived
by the SAS task emldetect. Emldetect uses an internal threshold of 6
arcseconds (before positional fitting) for splitting a source into two.
N_Blend
The number of simultaneously fit sources taking into account blended sources.
EP_Flux
The EPIC combined total band flux (erg/cm2/s). Fluxes are calculated by the
SAS tasks emldetect and by srcmatch for the various input bands. Note that
they correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5) are calculated from the respective band count rate using
the filter- and camera-dependent energy conversion factors given in Table 8
above and corrected for the dead time due to the read-out phase. These can be
0.0 if the detection has no counts. The EPIC flux in each band is the mean of
the band-specific detections in all cameras weighted by the errors. Combined
band fluxes for the individual cameras are the sum of the fluxes and errors
from each band (1 - 5).
EP_Flux_Error
The uncertainty in the EPIC combined total band flux (erg/cm2/s). The error
in the weighted mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5). The flux errors are
calculated from the respective band count rate error using the respective
energy conversion factors
EP_1_Flux
The EPIC band 1 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts. The EPIC flux in each band
is the mean of the band-specific detections in all cameras weighted by the
errors.
EP_1_Flux_Error
The uncertainty in EPIC band 1 flux (erg/cm2/s). The error in the weighted
mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5, 8, 9).
The flux errors are calculated from the respective band count rate error
using the respective energy conversion factors
EP_2_Flux
The EPIC band 2 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts. The EPIC flux in each band
is the mean of the band-specific detections in all cameras weighted by the
errors.
EP_2_Flux_Error
The uncertainty in EPIC band 2 flux (erg/cm2/s). The error in the weighted
mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5, 8, 9).
The flux errors are calculated from the respective band count rate error
using the respective energy conversion factors
EP_3_Flux
The EPIC band 3 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts. The EPIC flux in each band
is the mean of the band-specific detections in all cameras weighted by the
errors.
EP_3_Flux_Error
The uncertainty in the EPIC band 3 flux (erg/cm2/s). The error in the
weighted mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5, 8, 9).
The flux errors are calculated from the respective band count rate error
using the respective energy conversion factors
EP_4_Flux
The EPIC band 4 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts. The EPIC flux in each band
is the mean of the band-specific detections in all cameras weighted by the
errors.
EP_4_Flux_Error
The uncertainty in the EPIC band 4 flux (erg/cm2/s). The error in the
weighted mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5, 8, 9).
The flux errors are calculated from the respective band count rate error
using the respective energy conversion factors
EP_5_Flux
The EPIC band 5 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts. The EPIC flux in each band
is the mean of the band-specific detections in all cameras weighted by the
errors.
EP_5_Flux_Error
The uncertainty in the EPIC band 5 flux (erg/cm2/s). The error in the
weighted mean of the EPIC flux in band b is given by:
EP_b_FLUX_ERR = SQRT (1.0 / SUM (1 / ca_b_FLUX_ERR2 ))
where ca = PN, M1, M2, and b is the band (1, 2, 3, 4, 5, 8, 9).
The flux errors are calculated from the respective band count rate error
using the respective energy conversion factors
PN_Flux
The PN combined band flux (erg/cm2/s). Fluxes are calculated by the SAS
tasks emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. Combined band fluxes (band 8) for the individual
cameras are the sum of the fluxes from each band (1 - 5).
PN_Flux_Error
The uncertainty in the PN combined band flux (erg/cm2/s). Combined band
fluxes and errors (band 8) for the individual cameras are the sum of the
fluxes and errors from each band (1 - 5).
PN_1_Flux
The PN band 1 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
PN_1_Flux_Error
The uncertainty in the PN band 1 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
PN_2_Flux
The PN band 2 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
PN_2_Flux_Error
The uncertainty in the PN band 2 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
PN_3_Flux
The PN band 3 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
PN_3_Flux_Error
The uncertainty in the PN band 3 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
PN_4_Flux
The PN band 4 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
PN_4_Flux_Error
The uncertainty in the PN band 4 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
PN_5_Flux
The PN band 5 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
PN_5_Flux_Error
The uncertainty in the PN band 5 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M1_Flux
The M1 combined band flux (erg/cm2/s). Fluxes are calculated by the SAS
tasks emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. Combined band fluxes and errors (band 8) for the
individual cameras are the sum of the fluxes and errors from each band (1 -
5).
M1_Flux_Error
The uncertainty in the M1 combined band flux (erg/cm2/s). Combined band
fluxes and errors (band 8) for the individual cameras are the sum of the
fluxes and errors from each band (1 - 5).
M1_1_Flux
The M1 band 1 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M1_1_Flux_Error
The uncertainty in the M1 band 1 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M1_2_Flux
The M1 band 2 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M1_2_Flux_Error
The uncertainty in the M1 band 2 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M1_3_Flux
The M1 band 3 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M1_3_Flux_Error
The uncertainty in the M1 band 3 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M1_4_Flux
The M1 band 4 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M1_4_Flux_Error
The uncertainty in the M1 band 4 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M1_5_Flux
The M1 band 5 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M1_5_Flux_Error
The uncertainty in the M1 band 5 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M2_Flux
The M2 combined band flux (erg/cm2/s). Fluxes are calculated by the SAS
tasks emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. Combined band fluxes and errors (band 8) for the
individual cameras are the sum of the fluxes and errors from each band (1 -
5).
M2_Flux_Error
The uncertainty in the M2 combined band flux (erg/cm2/s). Combined band
fluxes and errors (band 8) for the individual cameras are the sum of the
fluxes and errors from each band (1 - 5).
M2_1_Flux
The M2 band 1 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M2_1_Flux_Error
The uncertainty in the M2 band 1 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M2_2_Flux
The M2 band 2 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M2_2_Flux_Error
The uncertainty in the M2 band 2 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M2_3_Flux
The M2 band 3 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M2_3_Flux_Error
The uncertainty in the M2 band 3 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M2_4_Flux
The M2 band 4 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M2_4_Flux_Error
The uncertainty in the M2 band 4 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
M2_5_Flux
The M2 band 5 flux (erg/cm2/s). Fluxes are calculated by the SAS tasks
emldetect and by srcmatch for the various input bands. Note that they
correspond to the flux in the entire PSF and do not need any further
corrections for PSF losses. For the individual cameras, individual-band
fluxes (bands 1 - 5, 9) are calculated from the respective band count rate
using the filter- and camera-dependent energy conversion factors given in
Table 8 above and corrected for the dead time due to the read-out phase.
These can be 0.0 if the detection has no counts
M2_5_Flux_Error
The uncertainty in the M2 band 5 flux (erg/cm2/s). These errors are
calculated from the respective band count rate error using the respective
energy conversion factors.
EP_Rate
The EPIC combined band count rate (ct/s), as derived by the SAS task
emldetect. The individual-band count rate (bands 1 - 5, 9) is the
band-dependent source counts (ca_b_CTS) divided by the exposure map, which
combines the mirror vignetting, detector efficiency, bad pixels and CCD gaps,
and an OOT-factor (Out Of Time), depending on the PN modes (PN_SUBMODE). The
source counts and with it the count rates were implicitly background
subtracted during the fitting process. They correspond to the count rate in
the entire PSF and do not need any further corrections for PSF losses. Note
that rates can be 0.0 (but not negative) if the source is too faint in the
respective band to be detectable. The combined band count rate (band 8) for
each camera is calculated as the sum of the count rates in the individual
bands 1 - 5. The EPIC rates are the sum of the camera-specific count rates in
the respective band.
EP_Rate_Error
The uncertainty in the EPIC combined band count rate (ct/s).
PN_Rate
The PN combined total band count rate (ct/s), as derived by the SAS task
emldetect. The individual-band count rate (bands 1 - 5, 9) is the
band-dependent source counts (ca_b_CTS) divided by the exposure map, which
combines the mirror vignetting, detector efficiency, bad pixels and CCD gaps,
and an OOT-factor (Out Of Time), depending on the PN modes (PN_SUBMODE). The
source counts and with it the count rates were implicitly background
subtracted during the fitting process. They correspond to the count rate in
the entire PSF and do not need any further corrections for PSF losses. Note
that rates can be 0.0 (but not negative) if the source is too faint in the
respective band to be detectable.
PN_Rate_Error
The uncertainty in the PN combined total band count rate (ct/s).
PN_1_Rate
The PN band 1 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
PN_1_Rate_Error
The uncertainty in the PN band 1 count rate (ct/s).
PN_2_Rate
The PN band 2 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
PN_2_Rate_Error
The uncertainty in the PN band 2 count rate (ct/s).
PN_3_Rate
The PN band 3 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
PN_3_Rate_Error
The uncertainty in the PN band 3 count rate (ct/s).
PN_4_Rate
The PN band 4 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
PN_4_Rate_Error
The uncertainty in the PN band 4 count rate (ct/s).
PN_5_Rate
The PN band 5 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
PN_5_Rate_Error
The uncertainty in the PN band 5 count rate (ct/s).
M1_Rate
The M1 combined total band count rate (ct/s), as derived by the SAS task
emldetect. The individual-band count rate (bands 1 - 5, 9) is the
band-dependent source counts (ca_b_CTS) divided by the exposure map, which
combines the mirror vignetting, detector efficiency, bad pixels and CCD gaps,
and an OOT-factor (Out Of Time), depending on the PN modes (PN_SUBMODE). The
source counts and with it the count rates were implicitly background
subtracted during the fitting process. They correspond to the count rate in
the entire PSF and do not need any further corrections for PSF losses. Note
that rates can be 0.0 (but not negative) if the source is too faint in the
respective band to be detectable.
M1_Rate_Error
The uncertainty in the M1 combined band count rate (ct/s).
M1_1_Rate
The M1 band 1 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M1_1_Rate_Error
The uncertainty in the M1 band 1 count rate (ct/s).
M1_2_Rate
The M1 band 2 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M1_2_Rate_Error
The uncertainty in the M1 band 2 count rate (ct/s).
M1_3_Rate
The M1 band 3 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M1_3_Rate_Error
The uncertainty in the M1 band 3 count rate (ct/s).
M1_4_Rate
The M1 band 4 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M1_4_Rate_Error
The uncertainty in the M1 band 4 count rate (ct/s).
M1_5_Rate
The M1 band 5 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M1_5_Rate_Error
The uncertainty in the M1 band 5 count rate (ct/s).
M2_Rate
The M2 combined total band count rate (ct/s), as derived by the SAS task
emldetect. The individual-band count rate (bands 1 - 5, 9) is the
band-dependent source counts (ca_b_CTS) divided by the exposure map, which
combines the mirror vignetting, detector efficiency, bad pixels and CCD gaps,
and an OOT-factor (Out Of Time), depending on the PN modes (PN_SUBMODE). The
source counts and with it the count rates were implicitly background
subtracted during the fitting process. They correspond to the count rate in
the entire PSF and do not need any further corrections for PSF losses. Note
that rates can be 0.0 (but not negative) if the source is too faint in the
respective band to be detectable.
M2_Rate_Error
The uncertainty in the M2 combined band count rate (ct/s).
M2_1_Rate
The M2 band 1 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M2_1_Rate_Error
The uncertainty in the M2 band 1 count rate (ct/s).
M2_2_Rate
The M2 band 2 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M2_2_Rate_Error
The uncertainty in the M2 band 2 count rate (ct/s).
M2_3_Rate
The M2 band 3 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M2_3_Rate_Error
The uncertainty in the M2 band 3 count rate (ct/s).
M2_4_Rate
The M2 band 4 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M2_4_Rate_Error
The uncertainty in the M2 band 4 count rate (ct/s).
M2_5_Rate
The M2 band 5 count rate (ct/s), as derived by the SAS task emldetect. The
individual-band count rate (bands 1 - 5, 9) is the band-dependent source
counts (ca_b_CTS) divided by the exposure map, which combines the mirror
vignetting, detector efficiency, bad pixels and CCD gaps, and an OOT-factor
(Out Of Time), depending on the PN modes (PN_SUBMODE). The source counts and
with it the count rates were implicitly background subtracted during the
fitting process. They correspond to the count rate in the entire PSF and do
not need any further corrections for PSF losses. Note that rates can be 0.0
(but not negative) if the source is too faint in the respective band to be
detectable.
M2_5_Rate_Error
The uncertainty in the M2 band 5 count rate (ct/s).
EP_Cts
The EPIC combined total band source counts, as derived by the SAS task
emldetect. The individual-band source counts (not given in this catalog) are
derived under the total PSF (point spread function) and corrected for
background. The PSF is fitted on sub-images of radius 60 arcseconds in each
band (CUTRAD), which means, that in most cases at least 90% of the PSF (if
covered by the detector) was effectively used in the fit. Combined band
source counts (band 8) for each camera are calculated as the sum of the
source counts in the individual bands 1 - 5. The EPIC band 8 counts are the
sum of the (available) individual camera band 8 counts.
EP_Cts_Error
The uncertainty in the EPIC combined band source counts, being the
statistical 1-sigma error in the total source counts of the detection, as
derived by the SAS task emldetect.
PN_Cts
The PN combined total band source counts, as derived by the SAS task
emldetect. The individual-band source counts (not given in this catalog) are
derived under the total PSF (point spread function) and corrected for
background. The PSF is fitted on sub-images of radius 60 arcseconds in each
band (CUTRAD), which means, that in most cases at least 90% of the PSF (if
covered by the detector) was effectively used in the fit. Combined band
source counts (band 8) for each camera are calculated as the sum of the
source counts in the individual bands 1 - 5.
PN_Cts_Error
The uncertainty in the PN combined band source counts, being the statistical
1-sigma error in the total source counts of the detection, as derived by the
SAS task emldetect.
M1_Cts
The M1 combined total band source counts, as derived by the SAS task
emldetect. The individual-band source counts (not given in this catalog) are
derived under the total PSF (point spread function) and corrected for
background. The PSF is fitted on sub-images of radius 60 arcseconds in each
band (CUTRAD), which means, that in most cases at least 90% of the PSF (if
covered by the detector) was effectively used in the fit. Combined band
source counts (band 8) for each camera are calculated as the sum of the
source counts in the individual bands 1 - 5.
M1_Cts_Error
The uncertainty in the M1 combined total band source counts, being the
statistical 1-sigma error in the total source counts of the detection, as
derived by the SAS task emldetect.
M2_Cts
The M2 combined band source counts, as derived by the SAS task emldetect. The
individual-band source counts (not given in this catalog) are derived under
the total PSF (point spread function) and corrected for background. The PSF
is fitted on sub-images of radius 60 arcseconds in each band (CUTRAD), which
means, that in most cases at least 90% of the PSF (if covered by the
detector) was effectively used in the fit. Combined band source counts (band
8) for each camera are calculated as the sum of the source counts in the
individual bands 1 - 5.
M2_Cts_Error
The uncertainty in the M2 combined total band source counts, being the
statistical 1-sigma error in the total source counts of the detection, as
derived by the SAS task emldetect.
EP_Det_ML
The EPIC combined band detection likelihood. Maximum likelihoods are derived
by the SAS task emldetect. The individual-band maximum likelihood values
(bands 1 - 5, 9) stand for the detection likelihood of the source, L = - ln
p, where p is the probability of the detection occurring by chance. While the
detection likelihood of an extended source is computed in the same way,
systematic effects such as deviations between the real background and the
model, have a larger effect on extended sources and thus detection
likelihoods of extended sources are more uncertain. To calculate the maximum
likelihood values for the combined band 8 and EPIC the sum of the individual
likelihoods is being normalized to two degrees of freedom using the function
ML_corr = gammaq (ndof/2, ML), where ndof = 2 (for xpos,ypos) + N_images for
point sources, ndof = 3 (for xpos,ypos,extent) + N_images for extended
sources, gammaq = - ln (Q(a,x)) = - ln (1 - P(a,x)), and P is the incomplete
gamma function.
PN_Det_ML
The PN combined total band detection likelihood. Maximum likelihoods are
derived by the SAS task emldetect. The individual-band maximum likelihood
values (bands 1 - 5, 9) stand for the detection likelihood of the source, L =
- ln p, where p is the probability of the detection occurring by chance.
While the detection likelihood of an extended source is computed in the same
way, systematic effects such as deviations between the real background and
the model, have a larger effect on extended sources and thus detection
likelihoods of extended sources are more uncertain.
PN_1_Det_ML
The PN band 1 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
PN_2_Det_ML
The PN band 2 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
PN_3_Det_ML
The PN band 3 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
PN_4_Det_ML
The PN band 4 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
PN_5_Det_ML
The PN band 5 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M1_Det_ML
The M1 combined total band detection likelihood. Maximum likelihoods are
derived by the SAS task emldetect. The individual-band maximum likelihood
values (bands 1 - 5, 9) stand for the detection likelihood of the source, L =
- ln p, where p is the probability of the detection occurring by chance.
While the detection likelihood of an extended source is computed in the same
way, systematic effects such as deviations between the real background and
the model, have a larger effect on extended sources and thus detection
likelihoods of extended sources are more uncertain.
M1_1_Det_ML
The M1 band 1 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M1_2_Det_ML
The M1 band 2 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M1_3_Det_ML
The M1 band 3 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M1_4_Det_ML
The M1 band 4 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M1_5_Det_ML
The M1 band 5 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M2_Det_ML
The M2 combined total band detection likelihood. Maximum likelihoods are
derived by the SAS task emldetect. The individual-band maximum likelihood
values (bands 1 - 5, 9) stand for the detection likelihood of the source, L =
- ln p, where p is the probability of the detection occurring by chance.
While the detection likelihood of an extended source is computed in the same
way, systematic effects such as deviations between the real background and
the model, have a larger effect on extended sources and thus detection
likelihoods of extended sources are more uncertain.
M2_1_Det_ML
The M2 band 1 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M2_2_Det_ML
The M2 band 2 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M2_3_Det_ML
The M2 band 3 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M2_4_Det_ML
The M2 band 4 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
M2_5_Det_ML
The M2 band 5 detection likelihood. Maximum likelihoods are derived by the
SAS task emldetect. The individual-band maximum likelihood values (bands 1 -
5, 9) stand for the detection likelihood of the source, L = - ln p, where p
is the probability of the detection occurring by chance. While the detection
likelihood of an extended source is computed in the same way, systematic
effects such as deviations between the real background and the model, have a
larger effect on extended sources and thus detection likelihoods of extended
sources are more uncertain.
Extent
The total band extent, i.e., the weighted average of the EPIC extents in the
total band of all the detections of the source, in arcseconds. The extent radius
of a source detected as extended is determined by the SAS task emldetect
(see 2XMM UG Sec. 3.1.2 f).
It is derived by convolving a beta-model profile with the source PSF and fitting
the result to the source image. Anything below 6" or an extent likelihood
below 4 is considered to be a point source and the extent is set to zero.
To avoid non-converging fitting an upper limit of 80" is imposed.
Extent_Error
The 1-sigma symmetric uncertainty in the total band extent, in arcseconds, as
determined by the SAS task emldetect (see
2XMM UG Sec. 3.1.2 f),
which convolves a beta-model profile with the source PSF and fits the result
to the source image.
Extent_Neg_Err
The lower 1-sigma asymmetric uncertainty in the total band extent, in
arcseconds, as determined by the SAS task emldetect (see
2XMM UG Sec. 3.1.2 f),
which convolves a beta-model profile with the source PSF and fits the result
to the source image.
Extent_Pos_Err
The upper 1-sigma asymmetric uncertainty in the total band extent, in arcseconds, as determined
by the SAS task emldetect (see 2XMM UG Sec. 3.1.2 f),
which convolves a beta-model profile with the source PSF and fits the result to the source image.
Extent_ML
The total band detection likelihood of the extended source SRCID, i.e., the
largest of the extent likelihoods of all detections of this source. The
extent likelihood is the likelihood of the detection being extended as given
by EXTENT_ML = - ln (P) , where P is the probability of the extent occurring
by chance.
Stack_Det_ML
The detection maximum likelihood using fitting of the 5-band spectrum
(0.2-12.0 keV).Source detection on XMM-Newton EPIC observations uses
maximum-likelihood fits under Cash statistics. For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended.
Stack_Flux
The mean flux of the spectral detection based on the fitting of the 5-band
spectrum (0.2-12.0 keV). For 5XMM data the "stack_" values correspond to the
source-detection step, where the source flux of each source is kept constant
over all exposures and the spectrum in the five standard energy bands is
described by an absorbed power-law. Under these assumptions, the equations of
the maximum-likelihood detection take the same form and the same degrees of
freedom irrespective of the number of exposures in which a source is fitted.
The degrees of freedom are the source coordinates, the mean source flux, and
the spectral parameters -- column density and power-law index -- if the
source is fitted as point-like, and additionally the radius of the extent
model, if the source is fitted as extended.
Stack_Flux_Error
The 1-sigma symmetric error on the mean flux of the spectral detection based
on the fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the
"stack_" values correspond to the source-detection step, where the source
flux of each source is kept constant over all exposures and the spectrum in
the five standard energy bands is described by an absorbed power-law. Under
these assumptions, the equations of the maximum-likelihood detection take the
same form and the same degrees of freedom irrespective of the number of
exposures in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases. The total 1-sigma error on a parameter is the arithmetic mean of the
lower and the upper error if both are defined.
Stack_Flux_Neg_Err
The lower 1-sigma asymmetric error on the mean flux of the spectral detection
based on the fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the
"stack_" values correspond to the source-detection step, where the source
flux of each source is kept constant over all exposures and the spectrum in
the five standard energy bands is described by an absorbed power-law. Under
these assumptions, the equations of the maximum-likelihood detection take the
same form and the same degrees of freedom irrespective of the number of
exposures in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
Stack_Flux_Pos_Err
The upper 1-sigma asymmetric error on the mean flux of the spectral detection
based on the fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the
"stack_" values correspond to the source-detection step, where the source
flux of each source is kept constant over all exposures and the spectrum in
the five standard energy bands is described by an absorbed power-law. Under
these assumptions, the equations of the maximum-likelihood detection take the
same form and the same degrees of freedom irrespective of the number of
exposures in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
Stack_NH
The hydrogen column density based on the fitting of the 5-band spectrum
(0.2-12.0 keV). For 5XMM data the "stack_" values correspond to the
source-detection step, where the source flux of each source is kept constant
over all exposures and the spectrum in the five standard energy bands is
described by an absorbed power-law. Under these assumptions, the equations of
the maximum-likelihood detection take the same form and the same degrees of
freedom irrespective of the number of exposures in which a source is fitted.
The degrees of freedom are the source coordinates, the mean source flux, and
the spectral parameters -- column density and power-law index -- if the
source is fitted as point-like, and additionally the radius of the extent
model, if the source is fitted as extended.
Stack_NH_Error
The 1-sigma symmetric error on the hydrogen column density based on the
fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases. The total 1-sigma error on a parameter is the arithmetic mean of the
lower and the upper error if both are defined.
Stack_NH_Neg_Err
The lower 1-sigma asymmetric error on the hydrogen column density based on
the fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended.For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
Stack_NH_Pos_Err
The upper 1-sigma asymmetric error on the hydrogen column density based on
the fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended.For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
Stack_Gamma
The power-law index based on the fitting of the 5-band spectrum (0.2-12.0
keV). For 5XMM data the "stack_" values correspond to the source-detection
step, where the source flux of each source is kept constant over all
exposures and the spectrum in the five standard energy bands is described by
an absorbed power-law. Under these assumptions, the equations of the
maximum-likelihood detection take the same form and the same degrees of
freedom irrespective of the number of exposures in which a source is fitted.
The degrees of freedom are the source coordinates, the mean source flux, and
the spectral parameters -- column density and power-law index -- if the
source is fitted as point-like, and additionally the radius of the extent
model, if the source is fitted as extended.
Stack_Gamma_Error
The 1-sigma symmetric error on the power-law index based on the fitting of
the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_" values
correspond to the source-detection step, where the source flux of each source
is kept constant over all exposures and the spectrum in the five standard
energy bands is described by an absorbed power-law. Under these assumptions,
the equations of the maximum-likelihood detection take the same form and the
same degrees of freedom irrespective of the number of exposures in which a
source is fitted. The degrees of freedom are the source coordinates, the mean
source flux, and the spectral parameters -- column density and power-law
index -- if the source is fitted as point-like, and additionally the radius
of the extent model, if the source is fitted as extended. For each fit
parameter, the lower and upper confidence limit are calculated, searching for
the parameter values for which the minimum Cash statistics value plus one is
reached. If the calculation of an error component does not converge, this
component is now set to undefined in all cases. The total 1-sigma error on a
parameter is the arithmetic mean of the lower and the upper error if both are
defined.
Stack_Gamma_Neg_Err
The lower 1-sigma asymmetric error on the power-law index based on the
fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
Stack_Gamma_Pos_Err
The upper 1-sigma asymmetric error on the power-law index based on the
fitting of the 5-band spectrum (0.2-12.0 keV). For 5XMM data the "stack_"
values correspond to the source-detection step, where the source flux of each
source is kept constant over all exposures and the spectrum in the five
standard energy bands is described by an absorbed power-law. Under these
assumptions, the equations of the maximum-likelihood detection take the same
form and the same degrees of freedom irrespective of the number of exposures
in which a source is fitted. The degrees of freedom are the source
coordinates, the mean source flux, and the spectral parameters -- column
density and power-law index -- if the source is fitted as point-like, and
additionally the radius of the extent model, if the source is fitted as
extended. For each fit parameter, the lower and upper confidence limit are
calculated, searching for the parameter values for which the minimum Cash
statistics value plus one is reached. If the calculation of an error
component does not converge, this component is now set to undefined in all
cases.
PN_1_ECF
The energy conversion factor for PN in the 0.2-0.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
PN_2_ECF
The energy conversion factor for PN in the 0.5-1.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
PN_3_ECF
The energy conversion factor for PN in the 1.0-2.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
PN_4_ECF
The energy conversion factor for PN in the 2.0-4.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
PN_5_ECF
The energy conversion factor for PN in the 4.5-12.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M1_1_ECF
The energy conversion factor for MOS1 in the 0.2-0.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M1_2_ECF
The energy conversion factor for MOS1 in the 0.5-1.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M1_3_ECF
The energy conversion factor for MOS1 in the 1.0-2.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M1_4_ECF
The energy conversion factor for MOS1 in the 2.0-4.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M1_5_ECF
The energy conversion factor for MOS1 in the 4.5-12.0 keV band. The ECFs are extrapolated for each fitted pair of spectral parameters, for each fitted detector position, and for the instrumental setup on the fly over a grid of pre-compiled values. This conversion factor relates the measured count rates in each input image to the source detection.
M2_1_ECF
The energy conversion factor for MOS2 in the 0.2-0.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M2_2_ECF
The energy conversion factor for MOS2 in the 0.5-1.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M2_3_ECF
The energy conversion factor for MOS2 in the 1.0-2.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M2_4_ECF
The energy conversion factor for MOS2 in the 2.0-4.5 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
M2_5_ECF
The energy conversion factor for MOS2 in the 4.5-12.0 keV band. The ECFs are
extrapolated for each fitted pair of spectral parameters, for each fitted
detector position, and for the instrumental setup on the fly over a grid of
pre-compiled values. This conversion factor relates the measured count rates
in each input image to the source detection.
EP_HR1
The EPIC hardness ratio HR1 for bands 1 and 2. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
EPIC hardness ratios are calculated by the SAS task srcmatch and are averaged over all three cameras (PN, M1, M2). Note that no energy conversion factor was used and that the EPIC hardness ratios are de facto not hardness ratios but an equivalent number helpful to characterize the hardness of a source.
EP_HR1_Error
The uncertainty in the EPIC hardness ratio for bands 1 and 2. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
EP_HR2
The EPIC hardness ratio HR2 for bands 2 and 3. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
EPIC hardness ratios are calculated by the SAS task srcmatch and are averaged over all three cameras (PN, M1, M2). Note that no energy conversion factor was used and that the EPIC hardness ratios are de facto not hardness ratios but an equivalent number helpful to characterize the hardness of a source.
EP_HR2_Error
The uncertainty in the EPIC hardness ratio for bands 2 and 3. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
EP_HR3
The EPIC hardness ratio HR3 for bands 3 and 4. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
EPIC hardness ratios are calculated by the SAS task srcmatch and are averaged over all three cameras (PN, M1, M2). Note that no energy conversion factor was used and that the EPIC hardness ratios are de facto not hardness ratios but an equivalent number helpful to characterize the hardness of a source.
EP_HR3_Error
The uncertainty in the EPIC hardness ratio for bands 3 and 4. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
EP_HR4
The EPIC hardness ratio HR4 for bands 4 and 5. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
EPIC hardness ratios are calculated by the SAS task srcmatch and are averaged over all three cameras (PN, M1, M2). Note that no energy conversion factor was used and that the EPIC hardness ratios are de facto not hardness ratios but an equivalent number helpful to characterize the hardness of a source.
EP_HR4_Error
The uncertainty in the EPIC hardness ratio for bands 4 and 5. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
PN_HR1
The PN hardness ratio HR1 for bands 1 and 2. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
PN_HR1_Error
The uncertainty in the PN hardness ratio for bands 1 and 2. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
PN_HR2
The PN hardness ratio HR2 for bands 2 and 3. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
PN_HR2_Error
The uncertainty in the PN hardness ratio for bands 2 and 3. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
PN_HR3
The PN hardness ratio HR3 for bands 3 and 4. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
PN_HR3_Error
The uncertainty in the PN hardness ratio for bands 3 and 4. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
PN_HR4
The PN hardness ratio HR4 for bands 4 and 5. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
PN_HR4_Error
The uncertainty in the PN hardness ratio for bands 4 and 5. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M1_HR1
The M1 hardness ratio HR1 for bands 1 and 2. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M1_HR1_Error
The uncertainty in the M1 hardness ratio for bands 1 and 2. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M1_HR2
The M1 hardness ratio HR2 for bands 2 and 3. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M1_HR2_Error
The uncertainty in the M1 hardness ratio for bands 2 and 3. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M1_HR3
The M1 hardness ratio HR3 for bands 3 and 4. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M1_HR3_Error
The uncertainty in the M1 hardness ratio for bands 3 and 4. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M1_HR4
The M1 hardness ratio HR4 for bands 4 and 5. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M1_HR4_Error
The uncertainty in the M1 hardness ratio for bands 4 and 5. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M2_HR1
The M2 hardness ratio HR1 for bands 1 and 2. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M2_HR1_Error
The uncertainty in the M2 hardness ratio for bands 1 and 2. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M2_HR2
The M2 hardness ratio HR2 for bands 2 and 3. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M2_HR2_Error
The uncertainty in the M2 hardness ratio for bands 2 and 3. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M2_HR3
The M2 hardness ratio HR3 for bands 3 and 4. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M2_HR3_Error
The uncertainty in the M2 hardness ratio for bands 3 and 4. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
M2_HR4
The M2 hardness ratio HR4 for bands 4 and 5. The hardness ratios for each
camera are derived by the SAS task emldetect. They are defined as the ratio
between the bands A and B:
HR(A,B) = (band B - band A) / (band A + band B).
Note that in the case where the rate in one band is 0.0 (i.e., too faint to be detected in this band) the hardness ratio will be -1 or +1 which is only a lower or upper limit, respectively. In cases where the rate in both bands is zero, the hardness ratio is undefined (NULL).
There are four hardness ratios (n) using the following bands:
HR1: bands 1 & 2
HR2: bands 2 & 3
HR3: bands 3 & 4
HR4: bands 4 & 5
M2_HR4_Error
The uncertainty in the M2 hardness ratio for bands 4 and 5. Errors are the
1-sigma error on the hardness ratio 1 as derived by the SAS task emldetect.
PN_1_Exposure
The PN band 1 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
PN_2_Exposure
The PN band 2 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
PN_3_Exposure
The PN band 3 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
PN_4_Exposure
The PN band 4 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
PN_5_Exposure
The PN band 5 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M1_1_Exposure
The M1 band 1 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M1_2_Exposure
The M1 band 2 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M1_3_Exposure
The M1 band 3 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M1_4_Exposure
The M1 band 4 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M1_5_Exposure
The M1 band 5 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M2_1_Exposure
The M2 band 1 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M2_2_Exposure
The M2 band 2 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M2_3_Exposure
The M2 band 3 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M2_4_Exposure
The M2 band 4 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
M2_5_Exposure
The M2 band 5 exposure map value (s). The exposure maps are made by the SAS
task eexpmap; they combine the mirror vignetting, detector efficiency, bad
pixels and CCD gaps. The exposure map values in the catalog are given in
seconds and are derived by the SAS task emldetect as the PSF weighted mean of
the area of the sub-images (radius 60 arcseconds) in the individual-band
exposure maps.
PN_Bg
The total PN band background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
PN_1_Bg
The PN band 1 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
PN_2_Bg
The PN band 2 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
PN_3_Bg
The PN band 3 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
PN_4_Bg
The PN band 4 background map value (ct/pixel).
The background maps are made by the SAS task esplinemap; they are made using
a 12 x 12 nodes spline fit on the source-free individual-band images. The
background map values in the catalog are given in counts per pixel and are
derived by the SAS task emldetect as the background map value at the given
detection position. Note that the source fitting routine uses the background
map itself rather than the single value given here. The value is zero if the
detection position lies outside the FOV.
PN_5_Bg
The PN band 5 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_Bg
The total MOS1 band background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_1_Bg
The M1 band 1 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_2_Bg
The M1 band 2 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_3_Bg
The M1 band 3 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_4_Bg
The M1 band 4 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M1_5_Bg
The M1 band 5 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_Bg
The total MOS2 band background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_1_Bg
The M2 band 1 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_2_Bg
The M2 band 2 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_3_Bg
The M2 band 3 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_4_Bg
The M2 band 4 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
M2_5_Bg
The M2 band 5 background map value (ct/pixel). The background maps are made
by the SAS task esplinemap; they are made using a 12 x 12 nodes spline fit on
the source-free individual-band images. The background map values in the
catalog are given in counts per pixel and are derived by the SAS task
emldetect as the background map value at the given detection position. Note
that the source fitting routine uses the background map itself rather than
the single value given here. The value is zero if the detection position lies
outside the FOV.
EP_Ontime
The largest total good exposure time after GTI filtering, in seconds, of any
of the individual cameras used.
PN_Ontime
The PN total good exposure time after GTI filtering, in seconds, of the CCD
where the detection is positioned. Note that some source positions fall into
CCD gaps or outside of the detector and will have therefore a NULL given.
M1_Ontime
The M1 total good exposure time after GTI filtering, in seconds, of the CCD
where the detection is positioned. Note that some source positions fall into
CCD gaps or outside of the detector and will have therefore a NULL given.
M2_Ontime
The M2 total good exposure time after GTI filtering, in seconds, of the CCD
where the detection is positioned. Note that some source positions fall into
CCD gaps or outside of the detector and will have therefore a NULL given.
PN_Pileup
The estimate of the pile-up level in EPIC/PN detection. A value below 1
corresponds to negligible pile-up (less than a few % flux loss) while values
larger than 10 denote heavy pile-up.
M1_Pileup
The estimate of the pile-up level in EPIC/PN detection. A value below 1
corresponds to negligible pile-up (less than a few % flux loss) while values
larger than 10 denote heavy pile-up.
M2_Pileup
The estimate of the pile-up level in EPIC/PN detection. A value below 1
corresponds to negligible pile-up (less than a few % flux loss) while values
larger than 10 denote heavy pile-up.
PN_Maskfrac
The PSF-weighted mean of the PN detector coverage of a detection as derived
from the detection mask. It depends slightly on energy; only band 8 values
are given here which are the minimum of the energy-dependent maskfrac values.
Sources which have less than 0.15 of their PSF covered by the detector are
considered as being not detected.
M1_Maskfrac
The PSF-weighted mean of the M1 detector coverage of a detection as derived
from the detection mask. It depends slightly on energy; only band 8 values
are given here which are the minimum of the energy-dependent maskfrac values.
Sources which have less than 0.15 of their PSF covered by the detector are
considered as being not detected.
M2_Maskfrac
The PSF-weighted mean of the M2 detector coverage of a detection as derived
from the detection mask. It depends slightly on energy; only band 8 values
are given here which are the minimum of the energy-dependent maskfrac values.
Sources which have less than 0.15 of their PSF covered by the detector are
considered as being not detected.
Dist_Ref
The distance to the reference coordinates of the field is given in
arcminutes; they are derived by the SAS task emldetect (see
2XMM UG Sec. 3.1.2 f).
This is considered to be the same for all observations and the stacked
source.
EP_Offax
The smallest off-axis angle (the angular distance between the detection
position and the on-axis direction) of the individual camera values, in
arcminutes.
PN_Offax
The distance between the detection position and the on-axis position on the PN
detector, in arcminutes. Note that the off-axis angle for a camera can be
larger than 15 arcminutes when the detection is located outside the FOV of
that camera.
M1_Offax
The distance between the detection position and the on-axis position on the M1
detector, in arcminutes. Note that the off-axis angle for a camera can be
larger than 15 arcminutes when the detection is located outside the FOV of
that camera.
M2_Offax
The distance between the detection position and the on-axis position on the M2
detector, in arcminutes. Note that the off-axis angle for a camera can be
larger than 15 arcminutes when the detection is located outside the FOV of
that camera.
Tseries_Flag
This flag is set to T(rue) to indicate that the source has time series
in at least one exposure (see Sec. 3.6 of the UG at
http://xmmssc.irap.omp.eu/3XMM-DR4/UserGuide_xmmcat.html#OptSSPExtr).
Spectra_Flag
This flag is set to T(rue) to indicate that the source has a spectrum made
in at least one exposure (see Sec. 3.6 of the UG at
http://xmmssc.irap.omp.eu/3XMM-DR4/UserGuide_xmmcat.html#OptSSPExtr).
Chi2prob
The chi2 probability (based on the null hypothesis) that the source, as
detected by any of the cameras, is constant. The minimum value of the
available camera probabilities (CHI2PROB) is given. The Pearson's
approximation to chi2 for Poissonian data was used, in which the model is
used as the estimator of its own variance (see the documentation of ekstest
for a more detailed description). If more than one exposure (that is, time
series) is available for this source the smallest value of probability was
used. See
2XMM UG Sec. 3.1.4
for more details, but note also changes described in
3XMM UG Sec. 3.6.
Fvar
The fractional RMS variability amplitude (deriving from the normalized excess
variance) measured in the timeseries of the detection. Where multiple
exposures exist, it is for the one giving the largest probability of
variability (CHI2PROB). This quantity provides a measure of the amplitude of
variability in the timeseries, above purely statistical fluctuations. See
Sec. 3.9 for
more details.
Fvar_Error
The error on the fractional RMS variability amplitude for the timeseries of
the detection (PN_FVAR). See
Sec. 3.9 for
more details.
Var_Flag
This flag is set to T(rue) if the source was detected as variable (chi2
probability < 1E-5) in at least one exposure, to F(alse) if the source was
tested for variability but did not qualify as such, or to N(ull) or
U(ndefined) if there was no timeseries file for the given detection or
insufficient points were left in the timeseries after applying background
flare GTIs,. See Sec. 3.2.8 of the 2XMM UG at
http://xmmssc.irap.omp.eu/2XMM/UserGuide_xmmcat.html#CatVarFlag.
PN_1_Vig
The PN band 1 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
PN_2_Vig
The PN band 2 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
PN_3_Vig
The PN band 3 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
PN_4_Vig
The PN band 4 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
PN_5_Vig
The PN band 5 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M1_1_Vig
The M1 band 1 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M1_2_Vig
The M1 band 2 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M1_3_Vig
The M1 band 3 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M1_4_Vig
The M1 band 4 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M1_5_Vig
The M1 band 5 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M2_1_Vig
The M2 band 1 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M2_2_Vig
The M2 band 2 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M2_3_Vig
The M2 band 3 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M2_4_Vig
The M2 band 4 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
M2_5_Vig
The M2 band 5 vignetting value. The vignetting values in the catalog are
derived by the SAS task emldetect; they are a function of energy band and
off-axis angle. (Vignetting values used in the source parametrization come
from the vignetted exposure maps.)
Sum_Flag
The summary flag is an integer representation of the stacked source flags.
For a clean detection, all strings are "F", and the summary flag is "0". The
first ten components of the string flag encode low PSF coverage, a detection
close to a bright point-like or close to an extended source, a detection
close to a bad CCD area, each of which is summarized by a SUM_FLAG=1; a
probably spurious detection which is close to a bright detection or which is
significant in only one band or which is on a warm pixel each of which is
summarized by a SUM_FLAG=2. The eleventh character of the EP_FLAG indicates
the result of visual screening, during which the screeners mark problematic
detector areas like single reflection patterns and largely extended
background emission. It translates into a SUM_FLAG=3 and to SUM_FLAG=4 if it
is associated with one of the spurious or warm pixel flag (see Tables).
0 = Good
1 = if the warning flags EP_FLAG 1, 2, 3 or 9 set to true but not 7, 8, 10 or 11
2 = if the possibly-spurious or warm pixel flags EP_FLAG 7, 8 or 10 set to true but not the manual flag 11
3 = if the manual flag EP_FLAG 11 is set to true but not the spurious or warm pixel flags 7, 8 or 10
4 = if the manual flag 11 as well as one of the spurious or warm pixel flags 7, 8 or 10 are set to true
For details see Sec. 3.2.7 of the 2XMM UG.
EP_Flag
The EPIC flag string made of the flags 1 - 11 (counted from left to right): it combines the flags in each camera (PN_FLAG, M1_FLAG, M2_FLAG), that is, a flag is set in EP_FLAG if at least one of the camera-dependent flags is set. The 11th flag results from the manual screening, see table below. See 2XMM UG Sec. 3.1.2 h) and Sec. 3.2.6 for a detailed description of the flags.
0 = No warning issued
1 = PSF coverage < 50%
2 = Near a bright point-like source
3 = Near a bright extended source
4 = Extended near a bright point source
5 = Extended near a bright extended source
6 = Extended, significant in one band
7 = Extended, flag 4, 5, or 6
8 = On a bad pixel or CCD area
9 = Near a bad CCD area
10 = On a warm pixel
11 = Flagged during visual screening
PN_Flag
PN flag string made of the flags 1 - 10 (counted from left to right) for the
PN source detection. A flag is set to True according to the conditions
summarized below for the automatic flags and the manual flags. In cases where
the camera was not used in the source detection a dash is given. Where a
source was not detected by the PN the flags are all set to False (default).
0 = No warning issued
1 = PSF coverage < 50%
2 = Near a bright point-like source
3 = Near a bright extended source
4 = Extended near a bright point source
5 = Extended near a bright extended source
6 = Extended, significant in one band
7 = Extended, flag 4, 5, or 6
8 = On a bad pixel or CCD area
9 = Near a bad CCD area
M1_Flag
The MOS1 flag string made of the flags 1 - 10 (counted from left to right)
for the MOS1 source detection. A flag is set to True according to the
conditions summarized below. In cases where the camera was not used in the
source detection a dash is given. Where a source was not detected by the MOS1
the flags are all set to False (default).
0 = No warning issued
1 = PSF coverage < 50%
2 = Near a bright point-like source
3 = Near a bright extended source
4 = Extended near a bright point source
5 = Extended near a bright extended source
6 = Extended, significant in one band
7 = Extended, flag 4, 5, or 6
8 = On a bad pixel or CCD area
9 = Near a bad CCD area
M2_Flag
The MOS2 flag string made of the flags 1 - 10 (counted from left to right)
for the MOS2 source detection. A flag is set to True according to the
conditions summarized below. In cases where the camera was not used in the
source detection a dash is given. Where a source was not detected by the MOS2
the flags are all set to False (default).
0 = No warning issued
1 = PSF coverage < 50%
2 = Near a bright point-like source
3 = Near a bright extended source
4 = Extended near a bright point source
5 = Extended near a bright extended source
6 = Extended, significant in one band
7 = Extended, flag 4, 5, or 6
8 = On a bad pixel or CCD area
9 = Near a bad CCD area
Var_Chi2
The reduced chi-squared of the inter-observation variability in the full
(0.2-12.0 keV) bands, supposing a constant flux.
Var_Chi2_1
The reduced chi-squared of the inter-observation variability in the EPIC Band
1, supposing a constant flux.
Var_Chi2_2
The reduced chi-squared of the inter-observation variability in the EPIC Band
2, supposing a constant flux.
Var_Chi2_3
The reduced chi-squared of the inter-observation variability in the EPIC Band
3, supposing a constant flux.
Var_Chi2_4
The reduced chi-squared of the inter-observation variability in the EPIC Band
4, supposing a constant flux.
Var_Chi2_5
The reduced chi-squared of the inter-observation variability in the EPIC Band
5, supposing a constant flux.
Var_Prob
The probability that the inter-observation variability in the full (0.2-12.0)
is consistent with 0.
Var_Prob_1
The probability that the inter-observation variability in the EPIC Band 1 is
consistent with 0..
Var_Prob_2
The probability that the inter-observation variability in the EPIC Band 2 is
consistent with 0.
Var_Prob_3
The probability that the inter-observation variability in the EPIC Band 3 is
consistent with 0.
Var_Prob_4
The probability that the inter-observation variability in the EPIC Band 4 is
consistent with 0.
Var_Prob_5
The probability that the inter-observation variability in the EPIC Band 5 is
consistent with 0.
FRatio
The maximum inter-observation flux ratio in the full (0.2-12.0) band.
FRatio_Error
The 1-sigma error on the maximum inter-observation flux ratio in the full
(0.2-12.0) band.
FRatio_1
The maximum inter-observation flux ratio in the EPIC Band 1 band.
FRatio_1_Error
The 1-sigma error on the maximum inter-observation flux ratio in the EPIC
Band 1 band.
FRatio_2
The maximum inter-observation flux ratio in the EPIC Band 2 band.
FRatio_2_Error
The 1-sigma error on the maximum inter-observation flux ratio in the EPIC
Band 2 band.
FRatio_3
The maximum inter-observation flux ratio in the EPIC Band 3 band.
FRatio_3_Error
The 1-sigma error on the maximum inter-observation flux ratio in the EPIC
Band 3 band.
FRatio_4
The maximum inter-observation flux ratio in the EPIC Band 4 band.
FRatio_4_Error
The 1-sigma error on the maximum inter-observation flux ratio in the EPIC
Band 4 band.
FRatio_5
The maximum inter-observation flux ratio in the EPIC Band 5 band.
FRatio_5_Error
The 1-sigma error on the maximum inter-observation flux ratio in the EPIC
Band 5 band.
FluxVar
Maximum inter-observation flux ratio in the full (0.2-12.0) band in terms of
sigma.
FluxVar_1
Maximum inter-observation flux ratio in the EPIC Band 1 band in terms of
sigma.
FluxVar_2
Maximum inter-observation flux ratio in the EPIC Band 2 band in terms of
sigma.
FluxVar_3
Maximum inter-observation flux ratio in the EPIC Band 3 band in terms of
sigma.
FluxVar_4
Maximum inter-observation flux ratio in the EPIC Band 4 band in terms of
sigma.
FluxVar_5
Maximum inter-observation flux ratio in the EPIC Band 5 band in terms of
sigma.
Time
The start date of the earliest observation of any constituent detection of
the unique source.
End_Time
The end date of the last observation of any constituent detection of the
unique source.
XMM_Revolution
The XMM-Newton revolution number in which the observation took place.
PN_Submode
The PN observing mode. The options are full frame mode with the full FOV
exposed (in two sub-modes), and large window mode with only parts of the FOV
exposed, see Table 2.3 at
https://xmm-tools.cosmos.esa.int/external/xmm_user_support/documentation/uhb/epicmode.html.
M1_Submode
The M1 observing mode. The options are full frame mode with the full FOV
exposed, partial window mode with only parts of the central CCD exposed (in
different sub-modes, see Table 2.3 at
https://xmm-tools.cosmos.esa.int/external/xmm_user_support/documentation/uhb/epicmode.html), and timing
mode where the central CCD was not exposed ('Fast Uncompressed').
M2_Submode
The M2 observing mode. The options are full frame mode with the full FOV
exposed, partial window mode with only parts of the central CCD exposed (in
different sub-modes, see Table 2.3 at
https://xmm-tools.cosmos.esa.int/external/xmm_user_support/documentation/uhb/epicmode.html), and timing
mode where the central CCD was not exposed ('Fast Uncompressed').
PN_Filter
The type of PN filter used. The options are Thick, Medium, Thin1, Thin2, and
Open, depending on the efficiency of the optical blocking.
M1_Filter
The type of M1 filter used. The options are Thick, Medium, Thin1, and Open,
depending on the efficiency of the optical blocking.
M2_Filter
The type of M2 filter used. The options are Thick, Medium, Thin1, and Open,
depending on the efficiency of the optical blocking.
Classx_Class
The classification of the X-ray source as described in
Sec. 3.9 of the UG.
The classifications in 5XMM are AGN, stars, Galactic X-ray binaries,
cataclysmic variables, background AGN, extra-galactic X-ray binary and
extended sources.
Classx_Outlier
The outlier measure (maximum 10) which indicates the likelihood that a source
does not fit one of the 5XMM classifications i.e. AGN, stars, Galactic X-ray
binaries, cataclysmic variables, background AGN, extra-galactic X-ray binary
and extended sources, see
Sec. 3.9 of the UG.
The higher the value, the more likely none of the classes are adapted to the
source nature.
Classx_Prob_Agn
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as an AGN
(see Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
Classx_Prob_Star
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as a star (see
Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
Classx_Prob_Gal_Xrb
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as an X-ray
binary (see
Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
Classx_Prob_Gal_Cv
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as a
cataclysmic variable (see
Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
Classx_Prob_Bkg_Agn
The posterior probability resulting from the X-ray source classification which indicates the probability that a source is best described as a background AGN (see Sec. 3.9 of the UG). The closer to unity, the more the class describes the source nature.
Classx_Prob_Extragal_Xrb
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as an
extra-galactic X-ray binary (see
Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
Classx_Prob_Extended
The posterior probability resulting from the X-ray source classification
which indicates the probability that a source is best described as an
extended source (see
Sec. 3.9 of the UG).
The closer to unity, the more the class describes the source nature.
OM_SrcID
Identification of the Optical Monitor source in the SUSS catalog (version
6.2) following the matching procedure as described in
Sec. 3.7 of the UG.
OM_UVW2_AB_Mag
Magnitude measure of the OM source in the UVW2 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_UVW2_AB_Mag_Error
The error in the magnitude measure of the OM source in the UVW2 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_UVM2_AB_Mag
Magnitude measure of the OM source in the UVM2 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_UVM2_AB_Mag_Error
The error in the magnitude measure of the OM source in the UVM2 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_UVW1_AB_Mag
Magnitude measure of the OM source in the UVW1 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_UVW1_AB_Mag_Error
The error in the magnitude measure of the OM source in the UVW1 OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_U_AB_Mag
Magnitude measure of the OM source in the U OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_U_AB_Mag_Error
The error in the magnitude measure of the OM source in the U OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_B_AB_Mag
Magnitude measure of the OM source in the B OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_B_AB_Mag_Error
The error in the magnitude measure of the OM source in the B OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_V_AB_Mag
Magnitude measure of the OM source in the V OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_V_AB_Mag_Error
The error in the magnitude measure of the OM source in the V OM filter using the AB system, as described in
Sec. 3.7 of the UG.
OM_Match_Prob
The probability of the reliability of the EPIC and OM source match, carried out with an NWAY-like algorithm (Salvato et al. 20198), as described in
Sec. 3.7 of the UG.
OM_UVW2_Quality_Flag
The flag providing a measure of the quality of the OM source in the UVW2 filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_UVM2_Quality_Flag
The flag providing a measure of the quality of the OM source in the UVW2 filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_UVW1_Quality_Flag
The flag providing a measure of the quality of the OM source in the UVW1 filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_U_Quality_Flag
The flag providing a measure of the quality of the OM source in the U filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_B_Quality_Flag
The flag providing a measure of the quality of the OM source in the B filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_V_Quality_Flag
The flag providing a measure of the quality of the OM source in the V filter. Details are provided in
Sec. 3.7 of the UG. The quality flag is an integer equivalent to a binary number in which each bit corresponds to a different quality issue; a bit is set to 1 when a data quality concern is identified or otherwise set to 0. Sources with the highest quality in the corresponding photometric band will thus have a value of 0. The meaning of the quality flags are as follows:
bit 0 (value 1) = source on a bad pixel bit 1 (value 2) = source on a readout streak bit 2 (value 4) = source on a smoke-ring bit 3 (value 8) = source on a diffraction spike bit 4 (value 16) = source affected by Mod-8 pattern bit 5 (value 32) = source within the central enhancement bit 6 (value 64) = source near a bright source bit 7 (value 128) = source near the edge bit 8 (value 256) = point source within an extended source bit 9 (value 512) = weird source (bright pixel) bit 10 (value 1,024) = multiple exposure values within photometry aperture bit 11 (value 2,048) = the source is affected by the reduced sensitivity patch [**] bit 12 (value 4,096) = the source is too bright (rate > 0.97 c/frame)
OM_UVW2_Extended_Flag
The flag that provides a measure of the extent of the OM source in the UVW2 filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_UVM2_Extended_Flag
The flag that provides a measure of the extent of the OM source in the UVM2 filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_UVW1_Extended_Flag
The flag that provides a measure of the extent of the OM source in the UVW1 filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_U_Extended_Flag
The flag that provides a measure of the extent of the OM source in the U filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_B_Extended_Flag
The flag that provides a measure of the extent of the OM source in the B filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_V_Extended_Flag
The flag that provides a measure of the extent of the OM source in the V filter. The extended flag is set to 0 if the counterpart is consistent with the shape of a point source in the UVW2 band or 1 if the source appears extended. Note that it is possible for a source to appear point-like in one passband but have measurable extent in another. More details are provided in
Sec. 3.7 of the UG.
OM_UVW2_Chisq
The measure of the long-term variability of the OM source in UVW2 filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_UVW2_Chisq_DoF
The degrees of freedom in the chi2 measurement of the UVM2 filter, which is one less than the number of measurements in UVW2. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_UVM2_Chisq
The measure of the long-term variability of the OM source in UVM2 filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_UVM2_Chisq_DoF
The degrees of freedom in the chi2 measurement of the UVW1 filter, which is one less than the number of measurements in UVM2. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_UVW1_Chisq
The measure of the long-term variability of the OM source in UVW1 filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_UVW1_Chisq_DoF
The degrees of freedom in the chi2 measurement of the U filter, which is one less than the number of measurements in UVW1. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_U_Chisq
The measure of the long-term variability of the OM source in U filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_U_Chisq_DoF
The degrees of freedom in the chi2 measurement of the B filter, which is one less than the number of measurements in U. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_B_Chisq
The measure of the long-term variability of the OM source in B filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_B_Chisq_DoF
The degrees of freedom in the chi2 measurement of the V filter, which is one less than the number of measurements in B. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_V_Chisq
The measure of the long-term variability of the OM source in V filter, where a source has been detected in multiple XMM-Newton observations in the same XMM-OM passband and a chi2 value is computed for the sequence of magnitude measurements compared to a single, constant magnitude. The corresponding degrees of freedom is one less than the number of measurements in that band. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
OM_V_Chisq_DoF
The degrees of freedom in the chi2 measurement of the V filter, which is one less than the number of measurements in V. The chi2 divided by the degrees of freedom can be used as an indicator as to whether there is evidence for variability between observations in that XMM-OM passband. Where variability is suggested by the chi2, the individual measurements can be consulted in XMM-SUSS v.6.2, see the User Guide (Section 3.7).
WISE_Name
WISE counterpart from the All-Sky Release Catalog name, based on J2000 position determined using an NWAY-like algorithm (Salvato et al. 2018). See the User Guide (Section 3.7).
WISE_W1mag
The AB magnitude for the WISE counterpart in the W1 band. See the User Guide (Section 3.7).
WISE_W1mag_Error
The uncertainty on the AB magnitude for the WISE counterpart in the W1 band. See the User Guide (Section 3.7).
WISE_W2mag
The AB magnitude for the WISE counterpart in the W2 band. See the User Guide (Section 3.7).
WISE_W2mag_Error
The uncertainty on the AB magnitude for the WISE counterpart in the W2 band. See the User Guide (Section 3.7).
WISE_W3mag
The AB magnitude for the WISE counterpart in the W3 band. See the User Guide (Section 3.7).
WISE_W3mag_Error
The uncertainty on the AB magnitude for the WISE counterpart in the W3 band. See the User Guide (Section 3.7).
WISE_W4mag
The AB magnitude for the WISE counterpart in the W4 band. See the User Guide (Section 3.7).
WISE_W4mag_Error
The uncertainty on the AB magnitude for the WISE counterpart in the W4 band. See the User Guide (Section 3.7).
WISE_Match_Prob
The probability of the reliability of the EPIC and WISE source match, carried out with an NWAY-like algorithm (Salvato et al. 20198), as described in
Sec. 3.7 of the UG).
GaiaDR3_Source_ID
GAIA counterpart identification from the Data Release 3 (DR3), based on J2000 position determined using an NWAY-like algorithm cross-matching EPIC and GAIA DR3 (Salvato et al. 2018), see the User Guide (Section 3.7).
GaiaDR3_Parallax
The parallax measurement, in milliarcseconds, for the Gaia DR3 catalog source
counterpart.
GaiaDR3_Parallax_Error
The 1-sigma uncertainty on the parallax measurement, in milliarcseconds, for
the Gaia DR3 catalog source counterpart.
GaiaDR3_Parallax_Overerr
The ratio of the parallax over the 1-sigma uncertainty on the parallax for
the Gaia DR3 catalog source counterpart.
GaiaDR3_PM_RA
The proper motion measurement, in milliarcseconds per year, in the right
ascension of the GAIA counterpart.
GaiaDR3_PM_Dec
The proper motion measurement, in milliarcseconds per year, in the
declination of the GAIA counterpart.
GaiaDR3_Gmag
The g magnitude for the Gaia DR3 catalog source counterpart.
GaiaDR3_Bpmag
The Bp magnitude for the Gaia DR3 catalog source counterpart.
GaiaDR3_Rpmag
The Rp magnitude for the Gaia DR3 catalog source counterpart.
Gaia_Match_Prob
The probability of the reliability of the EPIC and Gaia DR3 source match,
carried out with an NWAY-like algorithm (Salvato et al. 20198), as described in
Sec. 3.7 of the UG).
Info_Counterparts
The link that provides further information on multiwavelength counterparts of
the source, including spectral energy distributions, as described in
(Sec. 5.5 of the UG).
GaiaDR3_Dist
The distance, in parsec, between the Gaia counterpart and the Sun.
Classopt_Class
The classification of the optical source as described in Section 3.9 of the users guide. The classifications in 5XMM are AGN, galaxies or stars.
Classopt_Prob_Star
The posterior probability resulting from the optical source classification which indicates the probability that a source is best described by a star, see Section 3.9 of the users guide. The closer to unity, the more the class describes the source nature.
Classopt_Prob_Agn
The posterior probability resulting from the optical source classification which indicates the probability that a source is best described by an AGN, see Section 3.9 of the users guide. The closer to unity, the more the class describes the source nature.
Classopt_Prob_Galaxy
The posterior probability resulting from the optical source classification which indicates the probability that a source is best described by a galaxy, see Section 3.9 of the users guide. The closer to unity, the more the class describes the source nature.
Spec_Flux_Pl
The absorbed flux determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Flux_PL_Neg_Err
The lower (1-sigma, 16th percentile) confidence limit for the absorbed flux determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Flux_PL_Pos_Err
The upper (1-sigma, 84th percentile) confidence limit for the absorbed flux determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_NH_Pl
The hydrogen column density determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_NH_PL_Neg_Err
The lower (1-sigma, 16th percentile) confidence limit for the hydrogen column density determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_NH_PL_Pos_Err
The upper (1-sigma, 84th percentile) confidence limit for the hydrogen column density determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Gamma_Pl
The photon index determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Gamma_PL_Neg_Err
The lower (1-sigma, 16th percentile) confidence limit for the photon index determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Gamma_PL_Pos_Err
The upper (1-sigma, 84th percentile) confidence limit photon index determined from fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Iin_Pl
The EPIC inter-instrument normalization used in fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Iin_PL_Neg_Err
The lower (1-sigma, 16th percentile) confidence limit for the EPIC inter-instrument normalization used in fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Iin_PL_Pos_Err
The upper (1-sigma, 84th percentile) confidence limit for the EPIC inter-instrument normalization used in fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_DoF_Pl
The number of degrees of freedom in the process of fitting an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Pvalue_Pl
The P value of the absorbed power law fit to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Spec_Flag_Pl
The flag providing an indication of the quality of the fitting process of an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide. Zero indicates no problem.
Spec_Info
The link that provides complementary information on the fitting process of an absorbed power law to the spectrum (0.2-12.0 keV) extracted for each detection with at least 50 EPIC counts, see Section 3.6 of the users guide.
Approx_Source_Var
The long-term variability factor obtained from multi X-ray mission data over
four decades. Provided for sources with variability >5, at ~95% confidence, see
Sec. 3.5 of the UG.
Redshift_Zsp
The redshift determined from optical/infra-red spectral fitting for the
source, see
Sec. 3.8 of the UG
of the users guide.
Redshift_Tpz_Z_Best
The photometric redshift (phot-z) determined using TPZ, a machine learning
algorithm (Carrasco Kind & Brunner, 2013), see
Sec. 3.8 of the UG
of the users guide.
Redshift_Tpz_Flag_Zconf
The error on the photometric redshift (phot-z) determined using TPZ. This
measure is the root mean square (RMS) of the intrinsic dispersion of the
method, where an RMS=0.06 is used. A high value of zConf means that the
probability is highly concentrated around the estimated photo-z. See
Sec. 3.8 of the UG
of the users guide.
Redshift_Lph_Z_Best
The photometric redshift (phot-z) determined using Le Phare, a template
fitting algorithm (Arnouts et al. 1999, Ilbert et al. 2006) see
Sec. 3.8 of the UG
of the users guide.
Redshift_Lph_Flag_Zconf
The error on the photometric redshift (phot-z) determined using the LePhare
Method. This measure is the root mean square (RMS) of the intrinsic
dispersion of the method, where an RMS=0.06 is used. A high value of zConf
means that the probability is highly concentrated around the estimated
photo-z. See
Sec. 3.8 of the UG
of the users guide.
Redshift_Info_Distance
The link that provides supplementary information on the photometric redshift
process determination, see
Sec. 3.8 of the UG
of the users guide for details.
Contact Person
Questions regarding the XMMSTACK database table can be addressed to the HEASARC Help Desk.Page Author: Browse Software Development Team
Last Modified: Wednesday, 10-Jun-2026 15:09:40 EDT
- HEASARC Director: Vacant
- NASA Official: Ryan Smallcomb
- Web Curator: J.D. Myers
- Last Modified: 10-Jun-2026