Finding quadruply imaged quasars with machine learning-I. Methods

A. Akhazhanov; A. More; A. Amini; C. Hazlett; T. Treu; S. Birrer; A. Shajib; K. Liao; C. Lemon; A. Agnello; B. Nord; M. Aguena; S. Allam; F. Andrade-Oliveira; J. Annis; D. Brooks; E. Buckley-Geer; D. L. Burke; A. Carnero Rosell; M. Carrasco Kind; J. Carretero; A. Choi; C. Conselice; M. Costanzi; L. N. Da Costa; M. E.S. Pereira; J. De Vicente; S. Desai; J. P. Dietrich; P. Doel; S. Everett; I. Ferrero; D. A. Finley; B. Flaugher; J. Frieman; J. Garciá-Bellido; D. W. Gerdes; D. Gruen; R. A. Gruendl; J. Gschwend; G. Gutierrez; S. R. Hinton; D. L. Hollowood; K. Honscheid; D. J. James; A. G. Kim; K. Kuehn; N. Kuropatkin; O. Lahav; M. Lima; H. Lin; M. A.G. Maia; M. March; F. Menanteau; R. Miquel; R. Morgan; A. Palmese; F. Paz-Chinchón; A. Pieres; A. A. Plazas Malagón; E. Sanchez; V. Scarpine; S. Serrano; I. Sevilla-Noarbe; M. Smith; M. Soares-Santos; E. Suchyta; M. E.C. Swanson; G. Tarle; C. To; T. N. Varga; J. Weller

doi:10.1093/mnras/stac925

Finding quadruply imaged quasars with machine learning-I. Methods

A. Akhazhanov
, A. More
, A. Amini
, C. Hazlett
, T. Treu
, S. Birrer
, A. Shajib
, K. Liao
, C. Lemon
, A. Agnello
, B. Nord
, M. Aguena
, S. Allam
, F. Andrade-Oliveira
, J. Annis
, D. Brooks
, E. Buckley-Geer
, D. L. Burke
, A. Carnero Rosell
, M. Carrasco Kind

J. Carretero, A. Choi, C. Conselice, M. Costanzi, L. N. Da Costa, M. E.S. Pereira, J. De Vicente, S. Desai, J. P. Dietrich, P. Doel, S. Everett, I. Ferrero, D. A. Finley, B. Flaugher, J. Frieman, J. Garciá-Bellido, D. W. Gerdes, D. Gruen, R. A. Gruendl, J. Gschwend, G. Gutierrez, S. R. Hinton, D. L. Hollowood, K. Honscheid, D. J. James, A. G. Kim, K. Kuehn, N. Kuropatkin, O. Lahav, M. Lima, H. Lin, M. A.G. Maia, M. March, F. Menanteau, R. Miquel, R. Morgan, A. Palmese, F. Paz-Chinchón, A. Pieres, A. A. Plazas Malagón, E. Sanchez, V. Scarpine, S. Serrano, I. Sevilla-Noarbe, M. Smith, M. Soares-Santos, E. Suchyta, M. E.C. Swanson, G. Tarle, C. To, T. N. Varga, J. Weller

Physics and Astronomy

University of California at Los Angeles
Nazarbayev University
Inter-University Centre for Astronomy and Astrophysics India
The University of Tokyo
The University of Chicago
Wuhan University
Swiss Federal Institute of Technology Lausanne
University of Copenhagen
Fermi National Accelerator Laboratory
Kavli Institute for Cosmolo Gical Physics
Laboratório Interinstitucional de e-Astronomia
Universidade Estadual Paulista Júlio de Mesquita Filho
University College London
Stanford University
SLAC National Accelerator Laboratory
University of Illinois at Urbana-Champaign
Institute for High Energy Physics
Ohio State University
University of Manchester
University of Nottingham
University of Trieste
Osservatorio Astronomico di Trieste
Observatório Nacional
University of Michigan, Ann Arbor
University of Hamburg
CIEMAT
Indian Institute of Technology Hyderabad
Ludwig Maximilian University of Munich
University of California at Santa Cruz
Universidad Autónoma de Madrid
University of Queensland
Harvard-Smithsonian Ctr. Astrophys.
Lawrence Berkeley National Laboratory
Macquarie University
Lowell Observatory
Universidade de São Paulo
University of Pennsylvania
ICREA
University of Wisconsin-Madison
University of Cambridge
Princeton University
Institute of Space Studies of Catalonia
CSICIEEC)
University of Southampton
Oak Ridge National Laboratory
Max Planck Institute for Extraterrestrial Physics

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Strongly lensed quadruply imaged quasars (quads) are extraordinary objects. They are very rare in the sky and yet they provide unique information about a wide range of topics, including the expansion history and the composition of the Universe, the distribution of stars and dark matter in galaxies, the host galaxies of quasars, and the stellar initial mass function. Finding them in astronomical images is a classic 'needle in a haystack' problem, as they are outnumbered by other (contaminant) sources by many orders of magnitude. To solve this problem, we develop state-of-the-art deep learning methods and train them on realistic simulated quads based on real images of galaxies taken from the Dark Energy Survey, with realistic source and deflector models, including the chromatic effects of microlensing. The performance of the best methods on a mixture of simulated and real objects is excellent, yielding area under the receiver operating curve in the range of 0.86-0.89. Recall is close to 100 per cent down to total magnitude i ∼21 indicating high completeness, while precision declines from 85 per cent to 70 per cent in the range i ∼17-21. The methods are extremely fast: Training on 2 million samples takes 20 h on a GPU machine, and 108 multiband cut-outs can be evaluated per GPU-hour. The speed and performance of the method pave the way to apply it to large samples of astronomical sources, bypassing the need for photometric pre-selection that is likely to be a major cause of incompleteness in current samples of known quads.

Original language	English
Pages (from-to)	2407-2421
Number of pages	15
Journal	Monthly Notices of the Royal Astronomical Society
Volume	513
Issue number	2
DOIs	https://doi.org/10.1093/mnras/stac925
State	Published - Jun 1 2022

Keywords

astronomical data bases: Surveys
gravitational lensing: Strong
methods: Statistical

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10.1093/mnras/stac925

Cite this

Akhazhanov, A., More, A., Amini, A., Hazlett, C., Treu, T., Birrer, S., Shajib, A., Liao, K., Lemon, C., Agnello, A., Nord, B., Aguena, M., Allam, S., Andrade-Oliveira, F., Annis, J., Brooks, D., Buckley-Geer, E., Burke, D. L., Carnero Rosell, A., ... Weller, J. (2022). Finding quadruply imaged quasars with machine learning-I. Methods. Monthly Notices of the Royal Astronomical Society, 513(2), 2407-2421. https://doi.org/10.1093/mnras/stac925

@article{64b61d958aa74fd1bf57cfdd73225887,

title = "Finding quadruply imaged quasars with machine learning-I. Methods",

abstract = "Strongly lensed quadruply imaged quasars (quads) are extraordinary objects. They are very rare in the sky and yet they provide unique information about a wide range of topics, including the expansion history and the composition of the Universe, the distribution of stars and dark matter in galaxies, the host galaxies of quasars, and the stellar initial mass function. Finding them in astronomical images is a classic 'needle in a haystack' problem, as they are outnumbered by other (contaminant) sources by many orders of magnitude. To solve this problem, we develop state-of-the-art deep learning methods and train them on realistic simulated quads based on real images of galaxies taken from the Dark Energy Survey, with realistic source and deflector models, including the chromatic effects of microlensing. The performance of the best methods on a mixture of simulated and real objects is excellent, yielding area under the receiver operating curve in the range of 0.86-0.89. Recall is close to 100 per cent down to total magnitude i ∼21 indicating high completeness, while precision declines from 85 per cent to 70 per cent in the range i ∼17-21. The methods are extremely fast: Training on 2 million samples takes 20 h on a GPU machine, and 108 multiband cut-outs can be evaluated per GPU-hour. The speed and performance of the method pave the way to apply it to large samples of astronomical sources, bypassing the need for photometric pre-selection that is likely to be a major cause of incompleteness in current samples of known quads.",

keywords = "astronomical data bases: Surveys, gravitational lensing: Strong, methods: Statistical",

author = "A. Akhazhanov and A. More and A. Amini and C. Hazlett and T. Treu and S. Birrer and A. Shajib and K. Liao and C. Lemon and A. Agnello and B. Nord and M. Aguena and S. Allam and F. Andrade-Oliveira and J. Annis and D. Brooks and E. Buckley-Geer and Burke, \{D. L.\} and \{Carnero Rosell\}, A. and \{Carrasco Kind\}, M. and J. Carretero and A. Choi and C. Conselice and M. Costanzi and \{Da Costa\}, \{L. N.\} and Pereira, \{M. E.S.\} and \{De Vicente\}, J. and S. Desai and Dietrich, \{J. P.\} and P. Doel and S. Everett and I. Ferrero and Finley, \{D. A.\} and B. Flaugher and J. Frieman and J. Garci{\'a}-Bellido and Gerdes, \{D. W.\} and D. Gruen and Gruendl, \{R. A.\} and J. Gschwend and G. Gutierrez and Hinton, \{S. R.\} and Hollowood, \{D. L.\} and K. Honscheid and James, \{D. J.\} and Kim, \{A. G.\} and K. Kuehn and N. Kuropatkin and O. Lahav and M. Lima and H. Lin and Maia, \{M. A.G.\} and M. March and F. Menanteau and R. Miquel and R. Morgan and A. Palmese and F. Paz-Chinch{\'o}n and A. Pieres and \{Plazas Malag{\'o}n\}, \{A. A.\} and E. Sanchez and V. Scarpine and S. Serrano and I. Sevilla-Noarbe and M. Smith and M. Soares-Santos and E. Suchyta and Swanson, \{M. E.C.\} and G. Tarle and C. To and Varga, \{T. N.\} and J. Weller",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s) Published by Oxford University Press on behalf of Royal Astronomical Society.",

year = "2022",

month = jun,

day = "1",

doi = "10.1093/mnras/stac925",

language = "English",

volume = "513",

pages = "2407--2421",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

number = "2",

}

Akhazhanov, A, More, A, Amini, A, Hazlett, C, Treu, T, Birrer, S, Shajib, A, Liao, K, Lemon, C, Agnello, A, Nord, B, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Brooks, D, Buckley-Geer, E, Burke, DL, Carnero Rosell, A, Carrasco Kind, M, Carretero, J, Choi, A, Conselice, C, Costanzi, M, Da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Everett, S, Ferrero, I, Finley, DA, Flaugher, B, Frieman, J, Garciá-Bellido, J, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kim, AG, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Lin, H, Maia, MAG, March, M, Menanteau, F, Miquel, R, Morgan, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Plazas Malagón, AA, Sanchez, E, Scarpine, V, Serrano, S, Sevilla-Noarbe, I, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Varga, TN & Weller, J 2022, 'Finding quadruply imaged quasars with machine learning-I. Methods', Monthly Notices of the Royal Astronomical Society, vol. 513, no. 2, pp. 2407-2421. https://doi.org/10.1093/mnras/stac925

TY - JOUR

T1 - Finding quadruply imaged quasars with machine learning-I. Methods

AU - Akhazhanov, A.

AU - More, A.

AU - Amini, A.

AU - Hazlett, C.

AU - Treu, T.

AU - Birrer, S.

AU - Shajib, A.

AU - Liao, K.

AU - Lemon, C.

AU - Agnello, A.

AU - Nord, B.

AU - Aguena, M.

AU - Allam, S.

AU - Andrade-Oliveira, F.

AU - Annis, J.

AU - Brooks, D.

AU - Buckley-Geer, E.

AU - Burke, D. L.

AU - Carnero Rosell, A.

AU - Carrasco Kind, M.

AU - Carretero, J.

AU - Choi, A.

AU - Conselice, C.

AU - Costanzi, M.

AU - Da Costa, L. N.

AU - Pereira, M. E.S.

AU - De Vicente, J.

AU - Desai, S.

AU - Dietrich, J. P.

AU - Doel, P.

AU - Everett, S.

AU - Ferrero, I.

AU - Finley, D. A.

AU - Flaugher, B.

AU - Frieman, J.

AU - Garciá-Bellido, J.

AU - Gerdes, D. W.

AU - Gruen, D.

AU - Gruendl, R. A.

AU - Gschwend, J.

AU - Gutierrez, G.

AU - Hinton, S. R.

AU - Hollowood, D. L.

AU - Honscheid, K.

AU - James, D. J.

AU - Kim, A. G.

AU - Kuehn, K.

AU - Kuropatkin, N.

AU - Lahav, O.

AU - Lima, M.

AU - Lin, H.

AU - Maia, M. A.G.

AU - March, M.

AU - Menanteau, F.

AU - Miquel, R.

AU - Morgan, R.

AU - Palmese, A.

AU - Paz-Chinchón, F.

AU - Pieres, A.

AU - Plazas Malagón, A. A.

AU - Sanchez, E.

AU - Scarpine, V.

AU - Serrano, S.

AU - Sevilla-Noarbe, I.

AU - Smith, M.

AU - Soares-Santos, M.

AU - Suchyta, E.

AU - Swanson, M. E.C.

AU - Tarle, G.

AU - To, C.

AU - Varga, T. N.

AU - Weller, J.

PY - 2022/6/1

Y1 - 2022/6/1

N2 - Strongly lensed quadruply imaged quasars (quads) are extraordinary objects. They are very rare in the sky and yet they provide unique information about a wide range of topics, including the expansion history and the composition of the Universe, the distribution of stars and dark matter in galaxies, the host galaxies of quasars, and the stellar initial mass function. Finding them in astronomical images is a classic 'needle in a haystack' problem, as they are outnumbered by other (contaminant) sources by many orders of magnitude. To solve this problem, we develop state-of-the-art deep learning methods and train them on realistic simulated quads based on real images of galaxies taken from the Dark Energy Survey, with realistic source and deflector models, including the chromatic effects of microlensing. The performance of the best methods on a mixture of simulated and real objects is excellent, yielding area under the receiver operating curve in the range of 0.86-0.89. Recall is close to 100 per cent down to total magnitude i ∼21 indicating high completeness, while precision declines from 85 per cent to 70 per cent in the range i ∼17-21. The methods are extremely fast: Training on 2 million samples takes 20 h on a GPU machine, and 108 multiband cut-outs can be evaluated per GPU-hour. The speed and performance of the method pave the way to apply it to large samples of astronomical sources, bypassing the need for photometric pre-selection that is likely to be a major cause of incompleteness in current samples of known quads.

AB - Strongly lensed quadruply imaged quasars (quads) are extraordinary objects. They are very rare in the sky and yet they provide unique information about a wide range of topics, including the expansion history and the composition of the Universe, the distribution of stars and dark matter in galaxies, the host galaxies of quasars, and the stellar initial mass function. Finding them in astronomical images is a classic 'needle in a haystack' problem, as they are outnumbered by other (contaminant) sources by many orders of magnitude. To solve this problem, we develop state-of-the-art deep learning methods and train them on realistic simulated quads based on real images of galaxies taken from the Dark Energy Survey, with realistic source and deflector models, including the chromatic effects of microlensing. The performance of the best methods on a mixture of simulated and real objects is excellent, yielding area under the receiver operating curve in the range of 0.86-0.89. Recall is close to 100 per cent down to total magnitude i ∼21 indicating high completeness, while precision declines from 85 per cent to 70 per cent in the range i ∼17-21. The methods are extremely fast: Training on 2 million samples takes 20 h on a GPU machine, and 108 multiband cut-outs can be evaluated per GPU-hour. The speed and performance of the method pave the way to apply it to large samples of astronomical sources, bypassing the need for photometric pre-selection that is likely to be a major cause of incompleteness in current samples of known quads.

KW - astronomical data bases: Surveys

KW - gravitational lensing: Strong

KW - methods: Statistical

UR - https://www.scopus.com/pages/publications/85130484125

U2 - 10.1093/mnras/stac925

DO - 10.1093/mnras/stac925

M3 - Article

AN - SCOPUS:85130484125

SN - 0035-8711

VL - 513

SP - 2407

EP - 2421

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 2

ER -

Finding quadruply imaged quasars with machine learning-I. Methods

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Keywords

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