Abstract
The volume of data that will be produced by new-generation surveys
requires automatic classification methods to select and analyse sources.
Indeed, this is the case for the search for strong gravitational lenses,
where the population of the detectable lensed sources is only a very
small fraction of the full source population. We apply for the first
time a morphological classification method based on a Convolutional
Neural Network (CNN) for recognizing strong gravitational lenses in 255
deg2 of the Kilo Degree Survey (KiDS), one of the
current-generation optical wide surveys. The CNN is currently optimized
to recognize lenses with Einstein radii ≳1.4 arcsec, about twice
the r-band seeing in KiDS. In a sample of 21 789 colour-magnitude
selected luminous red galaxies (LRGs), of which three are known lenses,
the CNN retrieves 761 strong-lens candidates and correctly classifies
two out of three of the known lenses. The misclassified lens has an
Einstein radius below the range on which the algorithm is trained. We
down-select the most reliable 56 candidates by a joint visual
inspection. This final sample is presented and discussed. A conservative
estimate based on our results shows that with our proposed method it
should be possible to find ˜100 massive LRG-galaxy lenses at z
≲ 0.4 in KiDS when completed. In the most optimistic scenario, this
number can grow considerably (to maximally ˜2400 lenses), when
widening the colour-magnitude selection and training the CNN to
recognize smaller image-separation lens systems.
Original language | English |
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Pages (from-to) | 1129-1150 |
Number of pages | 22 |
Journal | Monthly Notices of the Royal Astronomical Society |
Volume | 472 |
Issue number | 1 |
DOIs | |
Publication status | Published - 1-Nov-2017 |
Keywords
- gravitational lensing: strong
- methods: data analysis
- methods: statistical
- surveys
- galaxies: elliptical and lenticular
- cD
- ACS SURVEY
- 2-DIMENSIONAL KINEMATICS
- EARLY-TYPE GALAXIES
- POLAR-RING GALAXIES
- OPTICAL IMAGING SURVEYS
- INITIAL MASS FUNCTION
- DIGITAL SKY SURVEY
- TO-LIGHT RATIOS
- DARK-MATTER
- SLACS LENSES