Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field

R. Pearce-Casey; B. C. Nagam; J. Wilde; V. Busillo; L. Ulivi; I. T. Andika; A. Manjón-García; L. Leuzzi; P. Matavulj; S. Serjeant; M. Walmsley; J. A.Acevedo Barroso; C. M. O’Riordan; B. Clément; C. Tortora; T. E. Collett; F. Courbin; R. Gavazzi; R. B. Metcalf; R. Cabanac; H. M. Courtois; J. Crook-Mansour; L. Delchambre; G. Despali; L. R. Ecker; A. Franco; P. Holloway; K. Jahnke; G. Mahler; L. Marchetti; A. Melo; M. Meneghetti; O. Müller; A. A. Nucita; J. Pearson; K. Rojas; C. Scarlata; S. Schuldt; D. Sluse; S. H. Suyu; M. Vaccari; S. Vegetti; A. Verma; G. Vernardos; M. Bolzonella; M. Kluge; T. Saifollahi; M. Schirmer; C. Stone; A. Paulino-Afonso; L. Bazzanini; N. B. Hogg; L. V.E. Koopmans; S. Kruk; F. Mannucci; J. M. Bromley; A. Díaz-Sánchez; H. J. Dickinson; D. M. Powell; H. Bouy; R. Laureijs; B. Altieri; A. Amara; S. Andreon; C. Baccigalupi; M. Baldi; A. Balestra; S. Bardelli; P. Battaglia; D. Bonino; E. Branchini; M. Brescia; J. Brinchmann; A. Caillat; S. Camera; V. Capobianco; C. Carbone; J. Carretero; S. Casas; M. Castellano; G. Castignani; S. Cavuoti; A. Cimatti; C. Colodro-Conde; G. Congedo; C. J. Conselice; L. Conversi; Y. Copin; M. Cropper; A. Da Silva; H. Degaudenzi; G. De Lucia; A. M. Di Giorgio; J. Dinis; F. Dubath; X. Dupac; S. Dusini; M. Farina; S. Farrens; F. Faustini; S. Ferriol; M. Frailis; E. Franceschi; S. Galeotta; K. George; W. Gillard; B. Gillis; C. Giocoli; P. Gómez-Alvarez; A. Grazian; F. Grupp; S. V.H. Haugan; W. Holmes; I. Hook; F. Hormuth; A. Hornstrup; P. Hudelot; M. Jhabvala; B. Joachimi; E. Keihänen; S. Kermiche; A. Kiessling; M. Kilbinger; B. Kubik; M. Kümmel; M. Kunz; H. Kurki-Suonio; D. Le Mignant; S. Ligori; P. B. Lilje; V. Lindholm; I. Lloro; E. Maiorano; O. Mansutti; O. Marggraf; K. Markovic; M. Martinelli; N. Martinet; F. Marulli; R. Massey; E. Medinaceli; S. Mei; M. Melchior; Y. Mellier; E. Merlin; G. Meylan; M. Moresco; L. Moscardini; R. Nakajima; C. Neissner; R. C. Nichol; S. M. Niemi; J. W. Nightingale; C. Padilla; S. Paltani; F. Pasian; K. Pedersen; W. J. Percival; V. Pettorino; S. Pires; G. Polenta; M. Poncet; L. A. Popa; L. Pozzetti; F. Raison; A. Renzi; J. Rhodes; G. Riccio; E. Romelli; M. Roncarelli; E. Rossetti; R. Saglia; Z. Sakr; A. G. Sánchez; D. Sapone; B. Sartoris; P. Schneider; T. Schrabback; A. Secroun; G. Seidel; S. Serrano; C. Sirignano; G. Sirri; J. Skottfelt; L. Stanco; J. Steinwagner; P. Tallada-Crespí; I. Tereno; R. Toledo-Moreo; F. Torradeflot; I. Tutusaus; E. A. Valentijn; L. Valenziano; T. Vassallo; G. Verdoes Kleijn; A. Veropalumbo; Y. Wang; J. Weller; G. Zamorani; E. Zucca; C. Burigana; M. Calabrese; A. Mora; M. Pöntinen; V. Scottez; M. Viel; B. Margalef-Bentabol

doi:10.1051/0004-6361/202453152

Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field

R. Pearce-Casey^*
, B. C. Nagam
, J. Wilde
, V. Busillo
, L. Ulivi
, I. T. Andika
, A. Manjón-García
, L. Leuzzi
, P. Matavulj
, S. Serjeant
, M. Walmsley
, J. A.Acevedo Barroso
, C. M. O’Riordan
, B. Clément
, C. Tortora
, T. E. Collett
, F. Courbin
, R. Gavazzi
, R. B. Metcalf
, R. Cabanac

H. M. Courtois, J. Crook-Mansour, L. Delchambre, G. Despali, L. R. Ecker, A. Franco, P. Holloway, K. Jahnke, G. Mahler, L. Marchetti, A. Melo, M. Meneghetti, O. Müller, A. A. Nucita, J. Pearson, K. Rojas, C. Scarlata, S. Schuldt, D. Sluse, S. H. Suyu, M. Vaccari, S. Vegetti, A. Verma, G. Vernardos, M. Bolzonella, M. Kluge, T. Saifollahi, M. Schirmer, C. Stone, A. Paulino-Afonso, L. Bazzanini, N. B. Hogg, L. V.E. Koopmans, S. Kruk, F. Mannucci, J. M. Bromley, A. Díaz-Sánchez, H. J. Dickinson, D. M. Powell, H. Bouy, R. Laureijs, B. Altieri, A. Amara, S. Andreon, C. Baccigalupi, M. Baldi, A. Balestra, S. Bardelli, P. Battaglia, D. Bonino, E. Branchini, M. Brescia, J. Brinchmann, A. Caillat, S. Camera, V. Capobianco, C. Carbone, J. Carretero, S. Casas, M. Castellano, G. Castignani, S. Cavuoti, A. Cimatti, C. Colodro-Conde, G. Congedo, C. J. Conselice, L. Conversi, Y. Copin, M. Cropper, A. Da Silva, H. Degaudenzi, G. De Lucia, A. M. Di Giorgio, J. Dinis, F. Dubath, X. Dupac, S. Dusini, M. Farina, S. Farrens, F. Faustini, S. Ferriol, M. Frailis, E. Franceschi, S. Galeotta, K. George, W. Gillard, B. Gillis, C. Giocoli, P. Gómez-Alvarez, A. Grazian, F. Grupp, S. V.H. Haugan, W. Holmes, I. Hook, F. Hormuth, A. Hornstrup, P. Hudelot, M. Jhabvala, B. Joachimi, E. Keihänen, S. Kermiche, A. Kiessling, M. Kilbinger, B. Kubik, M. Kümmel, M. Kunz, H. Kurki-Suonio, D. Le Mignant, S. Ligori, P. B. Lilje, V. Lindholm, I. Lloro, E. Maiorano, O. Mansutti, O. Marggraf, K. Markovic, M. Martinelli, N. Martinet, F. Marulli, R. Massey, E. Medinaceli, S. Mei, M. Melchior, Y. Mellier, E. Merlin, G. Meylan, M. Moresco, L. Moscardini, R. Nakajima, C. Neissner, R. C. Nichol, S. M. Niemi, J. W. Nightingale, C. Padilla, S. Paltani, F. Pasian, K. Pedersen, W. J. Percival, V. Pettorino, S. Pires, G. Polenta, M. Poncet, L. A. Popa, L. Pozzetti, F. Raison, A. Renzi, J. Rhodes, G. Riccio, E. Romelli, M. Roncarelli, E. Rossetti, R. Saglia, Z. Sakr, A. G. Sánchez, D. Sapone, B. Sartoris, P. Schneider, T. Schrabback, A. Secroun, G. Seidel, S. Serrano, C. Sirignano, G. Sirri, J. Skottfelt, L. Stanco, J. Steinwagner, P. Tallada-Crespí, I. Tereno, R. Toledo-Moreo, F. Torradeflot, I. Tutusaus, E. A. Valentijn, L. Valenziano, T. Vassallo, G. Verdoes Kleijn, A. Veropalumbo, Y. Wang, J. Weller, G. Zamorani, E. Zucca, C. Burigana, M. Calabrese, A. Mora, M. Pöntinen, V. Scottez, M. Viel, B. Margalef-Bentabol

^*Corresponding author for this work

Open University Milton Keynes
University of Groningen
National Institute for Nuclear Physics
Osservatorio Astrofisico Di Arcetri, Florence
Max Planck Institute for Astrophysics
Technical University of Cartagena
Istituto di Astrofisica Spaziale e Fisica Cosmica di Bologna
University of Applied Sciences Northwestern Switzerland
University of Manchester
Swiss Federal Institute of Technology Lausanne
Osservatorio Astronomico di Capodimonte
University of Portsmouth
ICREA
Institut d’Astrophysique de Paris
University of Bologna
Université Paul Sabatier Toulouse III
Institut national de physique nucléaire et de physique des particules
University of Cape Town
STAR Institute
Ludwig Maximilian University of Munich
University of Salento
University of Oxford
Max Planck Institute for Astronomy
Durham University
Technical University of Munich
University of Minnesota Twin Cities
American Museum of Natural History
Max Planck Institute for Extraterrestrial Physics
Université de Strasbourg
University of Montreal
University of Porto
University of Ferrara
CNRS
European Space Astronomy Centre
IDEX Bordeaux
ESTEC
University of Surrey
Osservatorio Astronomico di Brera
International School for Advanced Studies
Astronomical Observatory of Padua
National Institute for Astrophysics
University of Genoa
Port d’Informació Científica
Osservatorio Astronomico Roma
Instituto de Astrofísica de Canarias
University of Edinburgh
ESRIN - ESA Centre for Earth Observation
Universite Claude Bernard Lyon 1
University College London
University of Lisbon
University of Geneva
Osservatorio Astronomico di Trieste
Université Paris-Saclay
University of Oslo
California Institute of Technology
Lancaster University
Felix Hormuth Engineering
NASA Goddard Space Flight Center
University of Helsinki
Netherlands Institute for Radio Astronomy
University of Bonn
Université Paris 7
Institute for High Energy Physics
Newcastle University
University of Copenhagen
University of Waterloo
Italian Space Agency
Centre national d'études spatiales
Institute of Space Science
University of Padua
Heidelberg University
Universidad de Chile
University of Innsbruck
Institute of Space Studies of Catalonia
CIEMAT
European Space Agency - ESA
Université catholique de Lille
University of Trieste
SRON Netherlands Institute for Space Research

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

The Euclid Wide Survey (EWS) is predicted to find approximately 170 000 galaxy-galaxy strong lenses from its lifetime observation of 14 000 deg² of the sky. Detecting this many lenses by visual inspection with professional astronomers and citizen scientists alone is infeasible. As a result, machine learning algorithms, particularly convolutional neural networks (CNNs), have been used as an automated method of detecting strong lenses, and have proven fruitful in finding galaxy-galaxy strong lens candidates, such that the usage of CNNs in lens identification has increased. We identify the major challenge to be the automatic detection of galaxy-galaxy strong lenses while simultaneously maintaining a low false positive rate, thus producing a pure and complete sample of strong lens candidates from Euclid with a limited need for visual inspection. One aim of this research is to have a quantified starting point on the achieved purity and completeness with our current version of CNN-based detection pipelines for the VIS images of EWS. This work is vital in preparing our CNN-based detection pipelines to be able to produce a pure sample of the >100 000 strong gravitational lensing systems widely predicted for Euclid. We select all sources with VIS I_E < 23 mag from the Euclid Early Release Observation imaging of the Perseus field. We apply a range of CNN architectures to detect strong lenses in these cutouts. All our networks perform extremely well on simulated data sets and their respective validation sets. However, when applied to real Euclid imaging, the highest lens purity is just ∼11%. Among all our networks, the false positives are typically identifiable by human volunteers as, for example, spiral galaxies, multiple sources, and artifacts, implying that improvements are still possible, perhaps via a second, more interpretable lens selection filtering stage. There is currently no alternative to human classification of CNN-selected lens candidates. Given the expected ∼10⁵ lensing systems in Euclid, this implies 10⁶ objects for human classification, which while very large is not in principle intractable and not without precedent.

Original language	English
Article number	A214
Journal	Astronomy and Astrophysics
Volume	696
Number of pages	22
ISSN	0004-6361
DOIs	https://doi.org/10.1051/0004-6361/202453152
Publication status	Published - 2025

Keywords

Dark matter
Large-scale structure of Universe
Methods: data analysis
Surveys

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Pearce-Casey, R., Nagam, B. C., Wilde, J., Busillo, V., Ulivi, L., Andika, I. T., Manjón-García, A., Leuzzi, L., Matavulj, P., Serjeant, S., Walmsley, M., Barroso, J. A. A., O’Riordan, C. M., Clément, B., Tortora, C., Collett, T. E., Courbin, F., Gavazzi, R., Metcalf, R. B., ... Margalef-Bentabol, B. (2025). Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field. Astronomy and Astrophysics, 696, Article A214. https://doi.org/10.1051/0004-6361/202453152

@article{926798fc3639440293179bd20246706b,

title = "Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field",

abstract = "The Euclid Wide Survey (EWS) is predicted to find approximately 170 000 galaxy-galaxy strong lenses from its lifetime observation of 14 000 deg2 of the sky. Detecting this many lenses by visual inspection with professional astronomers and citizen scientists alone is infeasible. As a result, machine learning algorithms, particularly convolutional neural networks (CNNs), have been used as an automated method of detecting strong lenses, and have proven fruitful in finding galaxy-galaxy strong lens candidates, such that the usage of CNNs in lens identification has increased. We identify the major challenge to be the automatic detection of galaxy-galaxy strong lenses while simultaneously maintaining a low false positive rate, thus producing a pure and complete sample of strong lens candidates from Euclid with a limited need for visual inspection. One aim of this research is to have a quantified starting point on the achieved purity and completeness with our current version of CNN-based detection pipelines for the VIS images of EWS. This work is vital in preparing our CNN-based detection pipelines to be able to produce a pure sample of the >100 000 strong gravitational lensing systems widely predicted for Euclid. We select all sources with VIS IE < 23 mag from the Euclid Early Release Observation imaging of the Perseus field. We apply a range of CNN architectures to detect strong lenses in these cutouts. All our networks perform extremely well on simulated data sets and their respective validation sets. However, when applied to real Euclid imaging, the highest lens purity is just ∼11\%. Among all our networks, the false positives are typically identifiable by human volunteers as, for example, spiral galaxies, multiple sources, and artifacts, implying that improvements are still possible, perhaps via a second, more interpretable lens selection filtering stage. There is currently no alternative to human classification of CNN-selected lens candidates. Given the expected ∼105 lensing systems in Euclid, this implies 106 objects for human classification, which while very large is not in principle intractable and not without precedent.",

keywords = "Dark matter, Large-scale structure of Universe, Methods: data analysis, Surveys",

author = "R. Pearce-Casey and Nagam, \{B. C.\} and J. Wilde and V. Busillo and L. Ulivi and Andika, \{I. T.\} and A. Manj{\'o}n-Garc{\'i}a and L. Leuzzi and P. Matavulj and S. Serjeant and M. Walmsley and Barroso, \{J. A.Acevedo\} and O{\textquoteright}Riordan, \{C. M.\} and B. Cl{\'e}ment and C. Tortora and Collett, \{T. E.\} and F. Courbin and R. Gavazzi and Metcalf, \{R. B.\} and R. Cabanac and Courtois, \{H. M.\} and J. Crook-Mansour and L. Delchambre and G. Despali and Ecker, \{L. R.\} and A. Franco and P. Holloway and K. Jahnke and G. Mahler and L. Marchetti and A. Melo and M. Meneghetti and O. M{\"u}ller and Nucita, \{A. A.\} and J. Pearson and K. Rojas and C. Scarlata and S. Schuldt and D. Sluse and Suyu, \{S. H.\} and M. Vaccari and S. Vegetti and A. Verma and G. Vernardos and M. Bolzonella and M. Kluge and T. Saifollahi and M. Schirmer and C. Stone and A. Paulino-Afonso and L. Bazzanini and Hogg, \{N. B.\} and Koopmans, \{L. V.E.\} and S. Kruk and F. Mannucci and Bromley, \{J. M.\} and A. D{\'i}az-S{\'a}nchez and Dickinson, \{H. J.\} and Powell, \{D. M.\} and H. Bouy and R. Laureijs and B. Altieri and A. Amara and S. Andreon and C. Baccigalupi and M. Baldi and A. Balestra and S. Bardelli and P. Battaglia and D. Bonino and E. Branchini and M. Brescia and J. Brinchmann and A. Caillat and S. Camera and V. Capobianco and C. Carbone and J. Carretero and S. Casas and M. Castellano and G. Castignani and S. Cavuoti and A. Cimatti and C. Colodro-Conde and G. Congedo and Conselice, \{C. J.\} and L. Conversi and Y. Copin and M. Cropper and \{Da Silva\}, A. and H. Degaudenzi and \{De Lucia\}, G. and \{Di Giorgio\}, \{A. M.\} and J. Dinis and F. Dubath and X. Dupac and S. Dusini and M. Farina and S. Farrens and F. Faustini and S. Ferriol and M. Frailis and E. Franceschi and S. Galeotta and K. George and W. Gillard and B. Gillis and C. Giocoli and P. G{\'o}mez-Alvarez and A. Grazian and F. Grupp and Haugan, \{S. V.H.\} and W. Holmes and I. Hook and F. Hormuth and A. Hornstrup and P. Hudelot and M. Jhabvala and B. Joachimi and E. Keih{\"a}nen and S. Kermiche and A. Kiessling and M. Kilbinger and B. Kubik and M. K{\"u}mmel and M. Kunz and H. Kurki-Suonio and \{Le Mignant\}, D. and S. Ligori and Lilje, \{P. B.\} and V. Lindholm and I. Lloro and E. Maiorano and O. Mansutti and O. Marggraf and K. Markovic and M. Martinelli and N. Martinet and F. Marulli and R. Massey and E. Medinaceli and S. Mei and M. Melchior and Y. Mellier and E. Merlin and G. Meylan and M. Moresco and L. Moscardini and R. Nakajima and C. Neissner and Nichol, \{R. C.\} and Niemi, \{S. M.\} and Nightingale, \{J. W.\} and C. Padilla and S. Paltani and F. Pasian and K. Pedersen and Percival, \{W. J.\} and V. Pettorino and S. Pires and G. Polenta and M. Poncet and Popa, \{L. A.\} and L. Pozzetti and F. Raison and A. Renzi and J. Rhodes and G. Riccio and E. Romelli and M. Roncarelli and E. Rossetti and R. Saglia and Z. Sakr and S{\'a}nchez, \{A. G.\} and D. Sapone and B. Sartoris and P. Schneider and T. Schrabback and A. Secroun and G. Seidel and S. Serrano and C. Sirignano and G. Sirri and J. Skottfelt and L. Stanco and J. Steinwagner and P. Tallada-Cresp{\'i} and I. Tereno and R. Toledo-Moreo and F. Torradeflot and I. Tutusaus and Valentijn, \{E. A.\} and L. Valenziano and T. Vassallo and Kleijn, \{G. Verdoes\} and A. Veropalumbo and Y. Wang and J. Weller and G. Zamorani and E. Zucca and C. Burigana and M. Calabrese and A. Mora and M. P{\"o}ntinen and V. Scottez and M. Viel and B. Margalef-Bentabol",

note = "Publisher Copyright: {\textcopyright} The Authors 2025.",

year = "2025",

doi = "10.1051/0004-6361/202453152",

language = "English",

volume = "696",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Pearce-Casey, R, Nagam, BC, Wilde, J, Busillo, V, Ulivi, L, Andika, IT, Manjón-García, A, Leuzzi, L, Matavulj, P, Serjeant, S, Walmsley, M, Barroso, JAA, O’Riordan, CM, Clément, B, Tortora, C, Collett, TE, Courbin, F, Gavazzi, R, Metcalf, RB, Cabanac, R, Courtois, HM, Crook-Mansour, J, Delchambre, L, Despali, G, Ecker, LR, Franco, A, Holloway, P, Jahnke, K, Mahler, G, Marchetti, L, Melo, A, Meneghetti, M, Müller, O, Nucita, AA, Pearson, J, Rojas, K, Scarlata, C, Schuldt, S, Sluse, D, Suyu, SH, Vaccari, M, Vegetti, S, Verma, A, Vernardos, G, Bolzonella, M, Kluge, M, Saifollahi, T, Schirmer, M, Stone, C, Paulino-Afonso, A, Bazzanini, L, Hogg, NB, Koopmans, LVE, Kruk, S, Mannucci, F, Bromley, JM, Díaz-Sánchez, A, Dickinson, HJ, Powell, DM, Bouy, H, Laureijs, R, Altieri, B, Amara, A, Andreon, S, Baccigalupi, C, Baldi, M, Balestra, A, Bardelli, S, Battaglia, P, Bonino, D, Branchini, E, Brescia, M, Brinchmann, J, Caillat, A, Camera, S, Capobianco, V, Carbone, C, Carretero, J, Casas, S, Castellano, M, Castignani, G, Cavuoti, S, Cimatti, A, Colodro-Conde, C, Congedo, G, Conselice, CJ, Conversi, L, Copin, Y, Cropper, M, Da Silva, A, Degaudenzi, H, De Lucia, G, Di Giorgio, AM, Dinis, J, Dubath, F, Dupac, X, Dusini, S, Farina, M, Farrens, S, Faustini, F, Ferriol, S, Frailis, M, Franceschi, E, Galeotta, S, George, K, Gillard, W, Gillis, B, Giocoli, C, Gómez-Alvarez, P, Grazian, A, Grupp, F, Haugan, SVH, Holmes, W, Hook, I, Hormuth, F, Hornstrup, A, Hudelot, P, Jhabvala, M, Joachimi, B, Keihänen, E, Kermiche, S, Kiessling, A, Kilbinger, M, Kubik, B, Kümmel, M, Kunz, M, Kurki-Suonio, H, Le Mignant, D, Ligori, S, Lilje, PB, Lindholm, V, Lloro, I, Maiorano, E, Mansutti, O, Marggraf, O, Markovic, K, Martinelli, M, Martinet, N, Marulli, F, Massey, R, Medinaceli, E, Mei, S, Melchior, M, Mellier, Y, Merlin, E, Meylan, G, Moresco, M, Moscardini, L, Nakajima, R, Neissner, C, Nichol, RC, Niemi, SM, Nightingale, JW, Padilla, C, Paltani, S, Pasian, F, Pedersen, K, Percival, WJ, Pettorino, V, Pires, S, Polenta, G, Poncet, M, Popa, LA, Pozzetti, L, Raison, F, Renzi, A, Rhodes, J, Riccio, G, Romelli, E, Roncarelli, M, Rossetti, E, Saglia, R, Sakr, Z, Sánchez, AG, Sapone, D, Sartoris, B, Schneider, P, Schrabback, T, Secroun, A, Seidel, G, Serrano, S, Sirignano, C, Sirri, G, Skottfelt, J, Stanco, L, Steinwagner, J, Tallada-Crespí, P, Tereno, I, Toledo-Moreo, R, Torradeflot, F, Tutusaus, I, Valentijn, EA, Valenziano, L, Vassallo, T, Kleijn, GV, Veropalumbo, A, Wang, Y, Weller, J, Zamorani, G, Zucca, E, Burigana, C, Calabrese, M, Mora, A, Pöntinen, M, Scottez, V, Viel, M & Margalef-Bentabol, B 2025, 'Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field', Astronomy and Astrophysics, vol. 696, A214. https://doi.org/10.1051/0004-6361/202453152

TY - JOUR

T1 - Euclid

T2 - Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field

AU - Pearce-Casey, R.

AU - Nagam, B. C.

AU - Wilde, J.

AU - Busillo, V.

AU - Ulivi, L.

AU - Andika, I. T.

AU - Manjón-García, A.

AU - Leuzzi, L.

AU - Matavulj, P.

AU - Serjeant, S.

AU - Walmsley, M.

AU - Barroso, J. A.Acevedo

AU - O’Riordan, C. M.

AU - Clément, B.

AU - Tortora, C.

AU - Collett, T. E.

AU - Courbin, F.

AU - Gavazzi, R.

AU - Metcalf, R. B.

AU - Cabanac, R.

AU - Courtois, H. M.

AU - Crook-Mansour, J.

AU - Delchambre, L.

AU - Despali, G.

AU - Ecker, L. R.

AU - Franco, A.

AU - Holloway, P.

AU - Jahnke, K.

AU - Mahler, G.

AU - Marchetti, L.

AU - Melo, A.

AU - Meneghetti, M.

AU - Müller, O.

AU - Nucita, A. A.

AU - Pearson, J.

AU - Rojas, K.

AU - Scarlata, C.

AU - Schuldt, S.

AU - Sluse, D.

AU - Suyu, S. H.

AU - Vaccari, M.

AU - Vegetti, S.

AU - Verma, A.

AU - Vernardos, G.

AU - Bolzonella, M.

AU - Kluge, M.

AU - Saifollahi, T.

AU - Schirmer, M.

AU - Stone, C.

AU - Paulino-Afonso, A.

AU - Bazzanini, L.

AU - Hogg, N. B.

AU - Koopmans, L. V.E.

AU - Kruk, S.

AU - Mannucci, F.

AU - Bromley, J. M.

AU - Díaz-Sánchez, A.

AU - Dickinson, H. J.

AU - Powell, D. M.

AU - Bouy, H.

AU - Laureijs, R.

AU - Altieri, B.

AU - Amara, A.

AU - Andreon, S.

AU - Baccigalupi, C.

AU - Baldi, M.

AU - Balestra, A.

AU - Bardelli, S.

AU - Battaglia, P.

AU - Bonino, D.

AU - Branchini, E.

AU - Brescia, M.

AU - Brinchmann, J.

AU - Caillat, A.

AU - Camera, S.

AU - Capobianco, V.

AU - Carbone, C.

AU - Carretero, J.

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PY - 2025

Y1 - 2025

N2 - The Euclid Wide Survey (EWS) is predicted to find approximately 170 000 galaxy-galaxy strong lenses from its lifetime observation of 14 000 deg2 of the sky. Detecting this many lenses by visual inspection with professional astronomers and citizen scientists alone is infeasible. As a result, machine learning algorithms, particularly convolutional neural networks (CNNs), have been used as an automated method of detecting strong lenses, and have proven fruitful in finding galaxy-galaxy strong lens candidates, such that the usage of CNNs in lens identification has increased. We identify the major challenge to be the automatic detection of galaxy-galaxy strong lenses while simultaneously maintaining a low false positive rate, thus producing a pure and complete sample of strong lens candidates from Euclid with a limited need for visual inspection. One aim of this research is to have a quantified starting point on the achieved purity and completeness with our current version of CNN-based detection pipelines for the VIS images of EWS. This work is vital in preparing our CNN-based detection pipelines to be able to produce a pure sample of the >100 000 strong gravitational lensing systems widely predicted for Euclid. We select all sources with VIS IE < 23 mag from the Euclid Early Release Observation imaging of the Perseus field. We apply a range of CNN architectures to detect strong lenses in these cutouts. All our networks perform extremely well on simulated data sets and their respective validation sets. However, when applied to real Euclid imaging, the highest lens purity is just ∼11%. Among all our networks, the false positives are typically identifiable by human volunteers as, for example, spiral galaxies, multiple sources, and artifacts, implying that improvements are still possible, perhaps via a second, more interpretable lens selection filtering stage. There is currently no alternative to human classification of CNN-selected lens candidates. Given the expected ∼105 lensing systems in Euclid, this implies 106 objects for human classification, which while very large is not in principle intractable and not without precedent.

AB - The Euclid Wide Survey (EWS) is predicted to find approximately 170 000 galaxy-galaxy strong lenses from its lifetime observation of 14 000 deg2 of the sky. Detecting this many lenses by visual inspection with professional astronomers and citizen scientists alone is infeasible. As a result, machine learning algorithms, particularly convolutional neural networks (CNNs), have been used as an automated method of detecting strong lenses, and have proven fruitful in finding galaxy-galaxy strong lens candidates, such that the usage of CNNs in lens identification has increased. We identify the major challenge to be the automatic detection of galaxy-galaxy strong lenses while simultaneously maintaining a low false positive rate, thus producing a pure and complete sample of strong lens candidates from Euclid with a limited need for visual inspection. One aim of this research is to have a quantified starting point on the achieved purity and completeness with our current version of CNN-based detection pipelines for the VIS images of EWS. This work is vital in preparing our CNN-based detection pipelines to be able to produce a pure sample of the >100 000 strong gravitational lensing systems widely predicted for Euclid. We select all sources with VIS IE < 23 mag from the Euclid Early Release Observation imaging of the Perseus field. We apply a range of CNN architectures to detect strong lenses in these cutouts. All our networks perform extremely well on simulated data sets and their respective validation sets. However, when applied to real Euclid imaging, the highest lens purity is just ∼11%. Among all our networks, the false positives are typically identifiable by human volunteers as, for example, spiral galaxies, multiple sources, and artifacts, implying that improvements are still possible, perhaps via a second, more interpretable lens selection filtering stage. There is currently no alternative to human classification of CNN-selected lens candidates. Given the expected ∼105 lensing systems in Euclid, this implies 106 objects for human classification, which while very large is not in principle intractable and not without precedent.

KW - Dark matter

KW - Large-scale structure of Universe

KW - Methods: data analysis

KW - Surveys

U2 - 10.1051/0004-6361/202453152

DO - 10.1051/0004-6361/202453152

M3 - Journal article

AN - SCOPUS:105003780882

SN - 0004-6361

VL - 696

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A214

ER -

Euclid: Searches for strong gravitational lenses using convolutional neural nets in Early Release Observations of the Perseus field

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