46 research outputs found
Models of gravitational lens candidates from Space Warps CFHTLS
We report modelling follow-up of recently-discovered gravitational-lens
candidates in the Canada France Hawaii Telescope Legacy Survey. Lens modelling
was done by a small group of specially-interested volunteers from the
SpaceWarps citizen-science community who originally found the candidate lenses.
Models are categorised according to seven diagnostics indicating (a) the image
morphology and how clear or indistinct it is, (b) whether the mass map and
synthetic lensed image appear to be plausible, and (c) how the lens-model mass
compares with the stellar mass and the abundance-matched halo mass. The lensing
masses range from ~10^11 Msun to >10^13 Msun. Preliminary estimates of the
stellar masses show a smaller spread in stellar mass (except for two lenses): a
factor of a few below or above ~10^11 Msun. Therefore, we expect the
stellar-to-total mass fraction to decline sharply as lensing mass increases.
The most massive system with a convincing model is J1434+522 (SW05). The two
low-mass outliers are J0206-095 (SW19) and J2217+015 (SW42); if these two are
indeed lenses, they probe an interesting regime of very low star-formation
efficiency. Some improvements to the modelling software (SpaghettiLens), and
discussion of strategies regarding scaling to future surveys with more and
frequent discoveries, are included.Comment: 16 pages, 10 figures, 1 table, online supplement table_1.csv contains
additional detailed numbers shown in table 1 and figure
Gravitational lens modelling in a citizen science context
We develop a method to enable collaborative modelling of gravitational lenses
and lens candidates, that could be used by non-professional lens enthusiasts.
It uses an existing free-form modelling program (glass), but enables the input
to this code to be provided in a novel way, via a user-generated diagram that
is essentially a sketch of an arrival-time surface. We report on an
implementation of this method, SpaghettiLens, which has been tested in a
modelling challenge using 29 simulated lenses drawn from a larger set created
for the Space Warps citizen science strong lens search. We find that volunteers
from this online community asserted the image parities and time ordering
consistently in some lenses, but made errors in other lenses depending on the
image morphology. While errors in image parity and time ordering lead to large
errors in the mass distribution, the enclosed mass was found to be more robust:
the model-derived Einstein radii found by the volunteers were consistent with
those produced by one of the professional team, suggesting that given the
appropriate tools, gravitational lens modelling is a data analysis activity
that can be crowd-sourced to good effect. Ideas for improvement are discussed,
these include (a) overcoming the tendency of the models to be shallower than
the correct answer in test cases, leading to systematic overestimation of the
Einstein radius by 10 per cent at present, and (b) detailed modelling of arcs.Comment: 10 pages, 12 figure
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Solar stormwatch: tracking solar eruptions
The Solar Stormwatch team reviews progress and prospects for this highly effective citizen-science project focused on the Sun
Galaxy zoo builder:morphological dependence of spiral galaxy pitch angle
Spiral structure is ubiquitous in the Universe, and the pitch angle of arms in spiral galaxies provide an important observable in efforts to discriminate between different mechanisms of spiral arm formation and evolution. In this paper, we present a hierarchical Bayesian approach to galaxy pitch angle determination, using spiral arm data obtained through the Galaxy Builder citizen science project. We present a new approach to deal with the large variations in pitch angle between different arms in a single galaxy, which obtains full posterior distributions on parameters. We make use of our pitch angles to examine previously reported links between bulge and bar strength and pitch angle, finding no correlation in our data (with a caveat that we use observational proxies for both bulge size and bar strength which differ from other work). We test a recent model for spiral arm winding, which predicts uniformity of the cotangent of pitch angle between some unknown upper and lower limits, finding our observations are consistent with this model of transient and recurrent spiral pitch angle as long as the pitch angle at which most winding spirals dissipate or disappear is larger than 10°. © 2021 The Author(s) 2021. Published by Oxford University Press on behalf of Royal Astronomical Society
Space Warps II. New Gravitational Lens Candidates from the CFHTLS Discovered through Citizen Science
We report the discovery of 29 promising (and 59 total) new lens candidates
from the CFHT Legacy Survey (CFHTLS) based on about 11 million classifications
performed by citizen scientists as part of the first Space Warps lens search.
The goal of the blind lens search was to identify lens candidates missed by
robots (the RingFinder on galaxy scales and ArcFinder on group/cluster scales)
which had been previously used to mine the CFHTLS for lenses. We compare some
properties of the samples detected by these algorithms to the Space Warps
sample and find them to be broadly similar. The image separation distribution
calculated from the Space Warps sample shows that previous constraints on the
average density profile of lens galaxies are robust. SpaceWarps recovers about
65% of known lenses, while the new candidates show a richer variety compared to
those found by the two robots. This detection rate could be increased to 80% by
only using classifications performed by expert volunteers (albeit at the cost
of a lower purity), indicating that the training and performance calibration of
the citizen scientists is very important for the success of Space Warps. In
this work we present the SIMCT pipeline, used for generating in situ a sample
of realistic simulated lensed images. This training sample, along with the
false positives identified during the search, has a legacy value for testing
future lens finding algorithms. We make the pipeline and the training set
publicly available.Comment: 23 pages, 12 figures, MNRAS accepted, minor to moderate changes in
this versio
Galaxy Zoo builder:four-component photometric decomposition of spiral galaxies guided by citizen science
Multicomponent modeling of galaxies is a valuable tool in the effort to quantitatively understand galaxy evolution, yet the use of the technique is plagued by issues of convergence, model selection, and parameter degeneracies. These issues limit its application over large samples to the simplest models, with complex models being applied only to very small samples. We attempt to resolve this dilemma of "quantity or quality" by developing a novel framework, built inside the Zooniverse citizen-science platform, to enable the crowdsourcing of model creation for Sloan Digital Sky Survey galaxies. We have applied the method, including a final algorithmic optimization step, on a test sample of 198 galaxies, and examine the robustness of this new method. We also compare it to automated fitting pipelines, demonstrating that it is possible to consistently recover accurate models that either show good agreement with, or improve on, prior work. We conclude that citizen science is a promising technique for modeling images of complex galaxies, and release our catalog of models
Gravitational lens modelling in a citizen science context
We develop a method to enable collaborative modelling of gravitational lenses and lens candidates, that could be used by non-professional lens enthusiasts. It uses an existing free-form modelling program (glass), but enables the input to this code to be provided in a novel way, via a user-generated diagram that is essentially a sketch of an arrival-time surface. We report on an implementation of this method, SpaghettiLens, which has been tested in a modelling challenge using 29 simulated lenses drawn from a larger set created for the Space Warps citizen science strong lens search. We find that volunteers from this online community asserted the image parities and time ordering consistently in some lenses, but made errors in other lenses depending on the image morphology. While errors in image parity and time ordering lead to large errors in the mass distribution, the enclosed mass was found to be more robust: the model-derived Einstein radii found by the volunteers were consistent with those produced by one of the professional team, suggesting that given the appropriate tools, gravitational lens modelling is a data analysis activity that can be crowd-sourced to good effect. Ideas for improvement are discussed; these include (a) overcoming the tendency of the models to be shallower than the correct answer in test cases, leading to systematic overestimation of the Einstein radius by 10 per cent at present, and (b) detailed modelling of arc
Space Warps: I. Crowd-sourcing the Discovery of Gravitational Lenses
We describe Space Warps, a novel gravitational lens discovery service that
yields samples of high purity and completeness through crowd-sourced visual
inspection. Carefully produced colour composite images are displayed to
volunteers via a web- based classification interface, which records their
estimates of the positions of candidate lensed features. Images of simulated
lenses, as well as real images which lack lenses, are inserted into the image
stream at random intervals; this training set is used to give the volunteers
instantaneous feedback on their performance, as well as to calibrate a model of
the system that provides dynamical updates to the probability that a classified
image contains a lens. Low probability systems are retired from the site
periodically, concentrating the sample towards a set of lens candidates. Having
divided 160 square degrees of Canada-France-Hawaii Telescope Legacy Survey
(CFHTLS) imaging into some 430,000 overlapping 82 by 82 arcsecond tiles and
displaying them on the site, we were joined by around 37,000 volunteers who
contributed 11 million image classifications over the course of 8 months. This
Stage 1 search reduced the sample to 3381 images containing candidates; these
were then refined in Stage 2 to yield a sample that we expect to be over 90%
complete and 30% pure, based on our analysis of the volunteers performance on
training images. We comment on the scalability of the SpaceWarps system to the
wide field survey era, based on our projection that searches of 10 images
could be performed by a crowd of 10 volunteers in 6 days.Comment: 21 pages, 13 figures, MNRAS accepted, minor to moderate changes in
this versio
Galaxy Zoo DESI: Detailed Morphology Measurements for 8.7M Galaxies in the DESI Legacy Imaging Surveys
We present detailed morphology measurements for 8.67 million galaxies in the
DESI Legacy Imaging Surveys (DECaLS, MzLS, and BASS, plus DES). These are
automated measurements made by deep learning models trained on Galaxy Zoo
volunteer votes. Our models typically predict the fraction of volunteers
selecting each answer to within 5-10\% for every answer to every GZ question.
The models are trained on newly-collected votes for DESI-LS DR8 images as well
as historical votes from GZ DECaLS. We also release the newly-collected votes.
Extending our morphology measurements outside of the previously-released
DECaLS/SDSS intersection increases our sky coverage by a factor of 4 (5,000 to
19,000 deg) and allows for full overlap with complementary surveys
including ALFALFA and MaNGA.Comment: 20 pages. Accepted at MNRAS. Catalog available via
https://zenodo.org/record/7786416. Pretrained models available via
https://github.com/mwalmsley/zoobot. Vizier and Astro Data Lab access not yet
available. With thanks to the Galaxy Zoo volunteer