Euclid preparation: XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning

B. Aussel; S. Kruk; M. Walmsley; M. Huertas-Company; M. Castellano; C. J. Conselice; M. Delli Veneri; H. Dominguez Sánchez; P. -A. Duc; U. Kuchner; A. La Marca; B. Margalef-Bentabol; F. R. Marleau; G. Stevens; Y. Toba; C. Tortora; L. Wang; N. Aghanim; B. Altieri; A. Amara; S. Andreon; N. Auricchio; M. Baldi; S. Bardelli; R. Bender; C. Bodendorf; D. Bonino; E. Branchini; M. Brescia; J. Brinchmann; S. Camera; V. Capobianco; C. Carbone; J. Carretero; S. Casas; S. Cavuoti; A. Cimatti; G. Congedo; L. Conversi; Y. Copin; F. Courbin; H. M. Courtois; M. Cropper; A. Da Silva; H. Degaudenzi; A. M. Di Giorgio; J. Dinis; F. Dubath; X. Dupac; S. Dusini; M. Farina; S. Farrens; S. Ferriol; S. Fotopoulou; M. Frailis; E. Franceschi; P. Franzetti; M. Fumana; S. Galeotta; B. Garilli; B. Gillis; C. Giocoli; A. Grazian; F. Grupp; S. V. H. Haugan; W. Holmes; I. Hook; F. Hormuth; A. Hornstrup; P. Hudelot; K. Jahnke; E. Keihänen; S. Kermiche; A. Kiessling; M. Kilbinger; B. Kubik; M. Kümmel; M. Kunz; H. Kurki-Suonio; R. Laureijs; S. Ligori; P. B. Lilje; V. Lindholm; I. Lloro; E. Maiorano; O. Mansutti; O. Marggraf; K. Markovic; N. Martinet; F. Marulli; R. Massey; S. Maurogordato; E. Medinaceli; S. Mei; Y. Mellier; M. Meneghetti; E. Merlin; G. Meylan; M. Moresco; L. Moscardini; E. Munari; S. -M. Niemi; 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; R. Rebolo; A. Renzi; J. Rhodes; G. Riccio; E. Romelli; M. Roncarelli; E. Rossetti; R. Saglia; D. Sapone; B. Sartoris; M. Schirmer; P. Schneider; A. Secroun; G. Seidel; S. Serrano; C. Sirignano; G. Sirri; L. Stanco; J. -L. Starck; P. Tallada-Crespi; A. N. Taylor; H. I. Teplitz; I. Tereno; R. Toledo-Moreo; F. Torradeflot; I. Tutusaus; E. A. Valentijn; L. Valenziano; T. Vassallo; A. Veropalumbo; Y. Wang; J. Weller; A. Zacchei; G. Zamorani; J. Zoubian; E. Zucca; A. Biviano; M. Bolzonella; A. Boucaud; E. Bozzo; C. Burigana; C. Colodro-Conde; D. Di Ferdinando; R. Farinelli; J. Graciá-Carpio; G. Mainetti; S. Marcin; N. Mauri; C. Neissner; A. A. Nucita; Z. Sakr; V. Scottez; M. Tenti; M. Viel; M. Wiesmann; Y. Akrami; V. Allevato; S. Anselmi; C. Baccigalupi; M. Ballardini; S. Borgani; A. S. Borlaff; H. Bretonnière; S. Bruton; R. Cabanac; A. Calabro; A. Cappi; C. S. Carvalho; G. Castignani; T. Castro; G. Cañas-Herrera; K. C. Chambers; J. Coupon; O. Cucciati; S. Davini; G. De Lucia; G. Desprez; S. Di Domizio; H. Dole; A. Diaz-Sánchez; J. A. Escartin Vigo; S. Escoffier; I. Ferrero; F. Finelli; L. Gabarra; K. Ganga; J. Garcia-Bellido; E. Gaztanaga; K. George; F. Giacomini; G. Gozaliasl; A. Gregorio; D. Guinet; A. Hall; H. Hildebrandt; A. Jimenez Munoz; J. J. E. Kajava; V. Kansal; D. Karagiannis; C. C. Kirkpatrick; L. Legrand; A. Loureiro; J. Macias-Perez; M. Magliocchetti; R. Maoli; M. Martinelli; C. J. A. P. Martins; S. Matthew; M. Maturi; L. Maurin; R. B. Metcalf; M. Migliaccio; P. Monaco; G. Morgante; S. Nadathur; Nicholas A. Walton; A. Peel; A. Pezzotta; V. Popa; C. Porciani; D. Potter; M. Pöntinen; P. Reimberg; P. -F. Rocci; A. G. Sánchez; A. Schneider; E. Sefusatti; M. Sereno; P. Simon; A. Spurio Mancini; S. A. Stanford; J. Steinwagner; G. Testera; M. Tewes; R. Teyssier; S. Toft; S. Tosi; A. Troja; M. Tucci; C. Valieri; J. Valiviita; D. Vergani; I. A. Zinchenko

doi:10.1051/0004-6361/202449609

Euclid preparation: XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning

B. Aussel
, S. Kruk
, M. Walmsley
, M. Huertas-Company
, M. Castellano
, C. J. Conselice
, M. Delli Veneri
, H. Dominguez Sánchez
, P. -A. Duc
, U. Kuchner
, A. La Marca
, B. Margalef-Bentabol
, F. R. Marleau
, G. Stevens
, Y. Toba
, C. Tortora
, L. Wang
, N. Aghanim
, B. Altieri
, A. Amara

S. Andreon, N. Auricchio, M. Baldi, S. Bardelli, R. Bender, C. Bodendorf, D. Bonino, E. Branchini, M. Brescia, J. Brinchmann, S. Camera, V. Capobianco, C. Carbone, J. Carretero, S. Casas, S. Cavuoti, A. Cimatti, G. Congedo, L. Conversi, Y. Copin, F. Courbin, H. M. Courtois, M. Cropper, A. Da Silva, H. Degaudenzi, A. M. Di Giorgio, J. Dinis, F. Dubath, X. Dupac, S. Dusini, M. Farina, S. Farrens, S. Ferriol, S. Fotopoulou, M. Frailis, E. Franceschi, P. Franzetti, M. Fumana, S. Galeotta, B. Garilli, B. Gillis, C. Giocoli, A. Grazian, F. Grupp, S. V. H. Haugan, W. Holmes, I. Hook, F. Hormuth, A. Hornstrup, P. Hudelot, K. Jahnke, E. Keihänen, S. Kermiche, A. Kiessling, M. Kilbinger, B. Kubik, M. Kümmel, M. Kunz, H. Kurki-Suonio, R. Laureijs, S. Ligori, P. B. Lilje, V. Lindholm, I. Lloro, E. Maiorano, O. Mansutti, O. Marggraf, K. Markovic, N. Martinet, F. Marulli, R. Massey, S. Maurogordato, E. Medinaceli, S. Mei, Y. Mellier, M. Meneghetti, E. Merlin, G. Meylan, M. Moresco, L. Moscardini, E. Munari, S. -M. Niemi, 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, R. Rebolo, A. Renzi, J. Rhodes, G. Riccio, E. Romelli, M. Roncarelli, E. Rossetti, R. Saglia, D. Sapone, B. Sartoris, M. Schirmer, P. Schneider, A. Secroun, G. Seidel, S. Serrano, C. Sirignano, G. Sirri, L. Stanco, J. -L. Starck, P. Tallada-Crespi, A. N. Taylor, H. I. Teplitz, I. Tereno, R. Toledo-Moreo, F. Torradeflot, I. Tutusaus, E. A. Valentijn, L. Valenziano, T. Vassallo, A. Veropalumbo, Y. Wang, J. Weller, A. Zacchei, G. Zamorani, J. Zoubian, E. Zucca, A. Biviano, M. Bolzonella, A. Boucaud, E. Bozzo, C. Burigana, C. Colodro-Conde, D. Di Ferdinando, R. Farinelli, J. Graciá-Carpio, G. Mainetti, S. Marcin, N. Mauri, C. Neissner, A. A. Nucita, Z. Sakr, V. Scottez, M. Tenti, M. Viel, M. Wiesmann, Y. Akrami, V. Allevato, S. Anselmi, C. Baccigalupi, M. Ballardini, S. Borgani, A. S. Borlaff, H. Bretonnière, S. Bruton, R. Cabanac, A. Calabro, A. Cappi, C. S. Carvalho, G. Castignani, T. Castro, G. Cañas-Herrera, K. C. Chambers, J. Coupon, O. Cucciati, S. Davini, G. De Lucia, G. Desprez, S. Di Domizio, H. Dole, A. Diaz-Sánchez, J. A. Escartin Vigo, S. Escoffier, I. Ferrero, F. Finelli, L. Gabarra, K. Ganga, J. Garcia-Bellido, E. Gaztanaga, K. George, F. Giacomini, G. Gozaliasl, A. Gregorio, D. Guinet, A. Hall, H. Hildebrandt, A. Jimenez Munoz, J. J. E. Kajava, V. Kansal, D. Karagiannis, C. C. Kirkpatrick, L. Legrand, A. Loureiro, J. Macias-Perez, M. Magliocchetti, R. Maoli, M. Martinelli, C. J. A. P. Martins, S. Matthew, M. Maturi, L. Maurin, R. B. Metcalf, M. Migliaccio, P. Monaco, G. Morgante, S. Nadathur, Nicholas A. Walton, A. Peel, A. Pezzotta, V. Popa, C. Porciani, D. Potter, M. Pöntinen, P. Reimberg, P. -F. Rocci, A. G. Sánchez, A. Schneider, E. Sefusatti, M. Sereno, P. Simon, A. Spurio Mancini, S. A. Stanford, J. Steinwagner, G. Testera, M. Tewes, R. Teyssier, S. Toft, S. Tosi, A. Troja, M. Tucci, C. Valieri, J. Valiviita, D. Vergani, I. A. Zinchenko

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

Abstract

The Euclid mission is expected to image millions of galaxies at high resolution, providing an extensive dataset with which to study galaxy evolution. Because galaxy morphology is both a fundamental parameter and one that is hard to determine for large samples, we investigate the application of deep learning in predicting the detailed morphologies of galaxies in Euclid using Zoobot, a convolutional neural network pretrained with 450 000 galaxies from the Galaxy Zoo project. We adapted Zoobot for use with emulated Euclid images generated based on Hubble Space Telescope COSMOS images and with labels provided by volunteers in the Galaxy Zoo: Hubble project. We experimented with different numbers of galaxies and various magnitude cuts during the training process. We demonstrate that the trained Zoobot model successfully measures detailed galaxy morphology in emulated Euclid images. It effectively predicts whether a galaxy has features and identifies and characterises various features, such as spiral arms, clumps, bars, discs, and central bulges. When compared to volunteer classifications, Zoobot achieves mean vote fraction deviations of less than 12% and an accuracy of above 91% for the confident volunteer classifications across most morphology types. However, the performance varies depending on the specific morphological class. For the global classes, such as disc or smooth galaxies, the mean deviations are less than 10%, with only 1000 training galaxies necessary to reach this performance. On the other hand, for more detailed structures and complex tasks, such as detecting and counting spiral arms or clumps, the deviations are slightly higher, of namely around 12% with 60 000 galaxies used for training. In order to enhance the performance on complex morphologies, we anticipate that a larger pool of labelled galaxies is needed, which could be obtained using crowd sourcing. We estimate that, with our model, the detailed morphology of approximately 800 million galaxies of the Euclid Wide Survey could be reliably measured and that approximately 230 million of these galaxies would display features. Finally, our findings imply that the model can be effectively adapted to new morphological labels. We demonstrate this adaptability by applying Zoobot to peculiar galaxies. In summary, our trained Zoobot CNN can readily predict morphological catalogues for Euclid images.

Original language	English
Article number	A274
Number of pages	26
Journal	Astronomy and Astrophysics
Volume	689
Early online date	19 Sept 2024
DOIs	https://doi.org/10.1051/0004-6361/202449609
Publication status	Published - Sept 2024

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10.1051/0004-6361/202449609Licence: CC BY

https://arxiv.org/abs/2402.10187Licence: CC BY

Cite this

Aussel, B., Kruk, S., Walmsley, M., Huertas-Company, M., Castellano, M., Conselice, C. J., Veneri, M. D., Sánchez, H. D., Duc, P. .-A., Kuchner, U., Marca, A. L., Margalef-Bentabol, B., Marleau, F. R., Stevens, G., Toba, Y., Tortora, C., Wang, L., Aghanim, N., Altieri, B., ... Zinchenko, I. A. (2024). Euclid preparation: XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning. Astronomy and Astrophysics, 689, Article A274. https://doi.org/10.1051/0004-6361/202449609

@article{43b8cd3a1e2a402f911bc8b529b0f9b4,

title = "Euclid preparation: XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning",

abstract = "The Euclid mission is expected to image millions of galaxies at high resolution, providing an extensive dataset with which to study galaxy evolution. Because galaxy morphology is both a fundamental parameter and one that is hard to determine for large samples, we investigate the application of deep learning in predicting the detailed morphologies of galaxies in Euclid using Zoobot, a convolutional neural network pretrained with 450 000 galaxies from the Galaxy Zoo project. We adapted Zoobot for use with emulated Euclid images generated based on Hubble Space Telescope COSMOS images and with labels provided by volunteers in the Galaxy Zoo: Hubble project. We experimented with different numbers of galaxies and various magnitude cuts during the training process. We demonstrate that the trained Zoobot model successfully measures detailed galaxy morphology in emulated Euclid images. It effectively predicts whether a galaxy has features and identifies and characterises various features, such as spiral arms, clumps, bars, discs, and central bulges. When compared to volunteer classifications, Zoobot achieves mean vote fraction deviations of less than 12\% and an accuracy of above 91\% for the confident volunteer classifications across most morphology types. However, the performance varies depending on the specific morphological class. For the global classes, such as disc or smooth galaxies, the mean deviations are less than 10\%, with only 1000 training galaxies necessary to reach this performance. On the other hand, for more detailed structures and complex tasks, such as detecting and counting spiral arms or clumps, the deviations are slightly higher, of namely around 12\% with 60 000 galaxies used for training. In order to enhance the performance on complex morphologies, we anticipate that a larger pool of labelled galaxies is needed, which could be obtained using crowd sourcing. We estimate that, with our model, the detailed morphology of approximately 800 million galaxies of the Euclid Wide Survey could be reliably measured and that approximately 230 million of these galaxies would display features. Finally, our findings imply that the model can be effectively adapted to new morphological labels. We demonstrate this adaptability by applying Zoobot to peculiar galaxies. In summary, our trained Zoobot CNN can readily predict morphological catalogues for Euclid images.",

author = "B. Aussel and S. Kruk and M. Walmsley and M. Huertas-Company and M. Castellano and Conselice, \{C. J.\} and Veneri, \{M. Delli\} and S{\'a}nchez, \{H. Dominguez\} and Duc, \{P. -A.\} and U. Kuchner and Marca, \{A. La\} and B. Margalef-Bentabol and Marleau, \{F. R.\} and G. Stevens and Y. Toba and C. Tortora and L. Wang and N. Aghanim and B. Altieri and A. Amara and S. Andreon and N. Auricchio and M. Baldi and S. Bardelli and R. Bender and C. Bodendorf and D. Bonino and E. Branchini and M. Brescia and J. Brinchmann and S. Camera and V. Capobianco and C. Carbone and J. Carretero and S. Casas and S. Cavuoti and A. Cimatti and G. Congedo and L. Conversi and Y. Copin and F. Courbin and Courtois, \{H. M.\} and M. Cropper and Silva, \{A. Da\} and H. Degaudenzi and Giorgio, \{A. M. Di\} and J. Dinis and F. Dubath and X. Dupac and S. Dusini and M. Farina and S. Farrens and S. Ferriol and S. Fotopoulou and M. Frailis and E. Franceschi and P. Franzetti and M. Fumana and S. Galeotta and B. Garilli and B. Gillis and C. Giocoli 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 K. Jahnke 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 R. Laureijs 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 N. Martinet and F. Marulli and R. Massey and S. Maurogordato and E. Medinaceli and S. Mei and Y. Mellier and M. Meneghetti and E. Merlin and G. Meylan and M. Moresco and L. Moscardini and E. Munari and Niemi, \{S. -M.\} 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 R. Rebolo and A. Renzi and J. Rhodes and G. Riccio and E. Romelli and M. Roncarelli and E. Rossetti and R. Saglia and D. Sapone and B. Sartoris and M. Schirmer and P. Schneider and A. Secroun and G. Seidel and S. Serrano and C. Sirignano and G. Sirri and L. Stanco and Starck, \{J. -L.\} and P. Tallada-Crespi and Taylor, \{A. N.\} and Teplitz, \{H. 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 A. Veropalumbo and Y. Wang and J. Weller and A. Zacchei and G. Zamorani and J. Zoubian and E. Zucca and A. Biviano and M. Bolzonella and A. Boucaud and E. Bozzo and C. Burigana and C. Colodro-Conde and Ferdinando, \{D. Di\} and R. Farinelli and J. Graci{\'a}-Carpio and G. Mainetti and S. Marcin and N. Mauri and C. Neissner and Nucita, \{A. A.\} and Z. Sakr and V. Scottez and M. Tenti and M. Viel and M. Wiesmann and Y. Akrami and V. Allevato and S. Anselmi and C. Baccigalupi and M. Ballardini and S. Borgani and Borlaff, \{A. S.\} and H. Bretonni{\`e}re and S. Bruton and R. Cabanac and A. Calabro and A. Cappi and Carvalho, \{C. S.\} and G. Castignani and T. Castro and G. Ca{\~n}as-Herrera and Chambers, \{K. C.\} and J. Coupon and O. Cucciati and S. Davini and Lucia, \{G. De\} and G. Desprez and Domizio, \{S. Di\} and H. Dole and A. Diaz-S{\'a}nchez and Vigo, \{J. A. Escartin\} and S. Escoffier and I. Ferrero and F. Finelli and L. Gabarra and K. Ganga and J. Garcia-Bellido and E. Gaztanaga and K. George and F. Giacomini and G. Gozaliasl and A. Gregorio and D. Guinet and A. Hall and H. Hildebrandt and Munoz, \{A. Jimenez\} and Kajava, \{J. J. E.\} and V. Kansal and D. Karagiannis and Kirkpatrick, \{C. C.\} and L. Legrand and A. Loureiro and J. Macias-Perez and M. Magliocchetti and R. Maoli and M. Martinelli and Martins, \{C. J. A. P.\} and S. Matthew and M. Maturi and L. Maurin and Metcalf, \{R. B.\} and M. Migliaccio and P. Monaco and G. Morgante and S. Nadathur and Walton, \{Nicholas A.\} and A. Peel and A. Pezzotta and V. Popa and C. Porciani and D. Potter and M. P{\"o}ntinen and P. Reimberg and Rocci, \{P. -F.\} and S{\'a}nchez, \{A. G.\} and A. Schneider and E. Sefusatti and M. Sereno and P. Simon and Mancini, \{A. Spurio\} and Stanford, \{S. A.\} and J. Steinwagner and G. Testera and M. Tewes and R. Teyssier and S. Toft and S. Tosi and A. Troja and M. Tucci and C. Valieri and J. Valiviita and D. Vergani and Zinchenko, \{I. A.\}",

year = "2024",

month = sep,

doi = "10.1051/0004-6361/202449609",

language = "English",

volume = "689",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Aussel, B, Kruk, S, Walmsley, M, Huertas-Company, M, Castellano, M, Conselice, CJ, Veneri, MD, Sánchez, HD, Duc, P-A, Kuchner, U, Marca, AL, Margalef-Bentabol, B, Marleau, FR, Stevens, G, Toba, Y, Tortora, C, Wang, L, Aghanim, N, Altieri, B, Amara, A, Andreon, S, Auricchio, N, Baldi, M, Bardelli, S, Bender, R, Bodendorf, C, Bonino, D, Branchini, E, Brescia, M, Brinchmann, J, Camera, S, Capobianco, V, Carbone, C, Carretero, J, Casas, S, Cavuoti, S, Cimatti, A, Congedo, G, Conversi, L, Copin, Y, Courbin, F, Courtois, HM, Cropper, M, Silva, AD, Degaudenzi, H, Giorgio, AMD, Dinis, J, Dubath, F, Dupac, X, Dusini, S, Farina, M, Farrens, S, Ferriol, S, Fotopoulou, S, Frailis, M, Franceschi, E, Franzetti, P, Fumana, M, Galeotta, S, Garilli, B, Gillis, B, Giocoli, C, Grazian, A, Grupp, F, Haugan, SVH, Holmes, W, Hook, I, Hormuth, F, Hornstrup, A, Hudelot, P, Jahnke, K, Keihänen, E, Kermiche, S, Kiessling, A, Kilbinger, M, Kubik, B, Kümmel, M, Kunz, M, Kurki-Suonio, H, Laureijs, R, Ligori, S, Lilje, PB, Lindholm, V, Lloro, I, Maiorano, E, Mansutti, O, Marggraf, O, Markovic, K, Martinet, N, Marulli, F, Massey, R, Maurogordato, S, Medinaceli, E, Mei, S, Mellier, Y, Meneghetti, M, Merlin, E, Meylan, G, Moresco, M, Moscardini, L, Munari, E, Niemi, S-M, Padilla, C, Paltani, S, Pasian, F, Pedersen, K, Percival, WJ, Pettorino, V, Pires, S, Polenta, G, Poncet, M, Popa, LA, Pozzetti, L, Raison, F, Rebolo, R, Renzi, A, Rhodes, J, Riccio, G, Romelli, E, Roncarelli, M, Rossetti, E, Saglia, R, Sapone, D, Sartoris, B, Schirmer, M, Schneider, P, Secroun, A, Seidel, G, Serrano, S, Sirignano, C, Sirri, G, Stanco, L, Starck, J-L, Tallada-Crespi, P, Taylor, AN, Teplitz, HI, Tereno, I, Toledo-Moreo, R, Torradeflot, F, Tutusaus, I, Valentijn, EA, Valenziano, L, Vassallo, T, Veropalumbo, A, Wang, Y, Weller, J, Zacchei, A, Zamorani, G, Zoubian, J, Zucca, E, Biviano, A, Bolzonella, M, Boucaud, A, Bozzo, E, Burigana, C, Colodro-Conde, C, Ferdinando, DD, Farinelli, R, Graciá-Carpio, J, Mainetti, G, Marcin, S, Mauri, N, Neissner, C, Nucita, AA, Sakr, Z, Scottez, V, Tenti, M, Viel, M, Wiesmann, M, Akrami, Y, Allevato, V, Anselmi, S, Baccigalupi, C, Ballardini, M, Borgani, S, Borlaff, AS, Bretonnière, H, Bruton, S, Cabanac, R, Calabro, A, Cappi, A, Carvalho, CS, Castignani, G, Castro, T, Cañas-Herrera, G, Chambers, KC, Coupon, J, Cucciati, O, Davini, S, Lucia, GD, Desprez, G, Domizio, SD, Dole, H, Diaz-Sánchez, A, Vigo, JAE, Escoffier, S, Ferrero, I, Finelli, F, Gabarra, L, Ganga, K, Garcia-Bellido, J, Gaztanaga, E, George, K, Giacomini, F, Gozaliasl, G, Gregorio, A, Guinet, D, Hall, A, Hildebrandt, H, Munoz, AJ, Kajava, JJE, Kansal, V, Karagiannis, D, Kirkpatrick, CC, Legrand, L, Loureiro, A, Macias-Perez, J, Magliocchetti, M, Maoli, R, Martinelli, M, Martins, CJAP, Matthew, S, Maturi, M, Maurin, L, Metcalf, RB, Migliaccio, M, Monaco, P, Morgante, G, Nadathur, S, Walton, NA, Peel, A, Pezzotta, A, Popa, V, Porciani, C, Potter, D, Pöntinen, M, Reimberg, P, Rocci, P-F, Sánchez, AG, Schneider, A, Sefusatti, E, Sereno, M, Simon, P, Mancini, AS, Stanford, SA, Steinwagner, J, Testera, G, Tewes, M, Teyssier, R, Toft, S, Tosi, S, Troja, A, Tucci, M, Valieri, C, Valiviita, J, Vergani, D & Zinchenko, IA 2024, 'Euclid preparation: XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning', Astronomy and Astrophysics, vol. 689, A274. https://doi.org/10.1051/0004-6361/202449609

TY - JOUR

T1 - Euclid preparation

T2 - XLIII. Measuring detailed galaxy morphologies for Euclid with machine learning

AU - Aussel, B.

AU - Kruk, S.

AU - Walmsley, M.

AU - Huertas-Company, M.

AU - Castellano, M.

AU - Conselice, C. J.

AU - Veneri, M. Delli

AU - Sánchez, H. Dominguez

AU - Duc, P. -A.

AU - Kuchner, U.

AU - Marca, A. La

AU - Margalef-Bentabol, B.

AU - Marleau, F. R.

AU - Stevens, G.

AU - Toba, Y.

AU - Tortora, C.

AU - Wang, L.

AU - Aghanim, N.

AU - Altieri, B.

AU - Amara, A.

AU - Andreon, S.

AU - Auricchio, N.

AU - Baldi, M.

AU - Bardelli, S.

AU - Bender, R.

AU - Bodendorf, C.

AU - Bonino, D.

AU - Branchini, E.

AU - Brescia, M.

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PY - 2024/9

Y1 - 2024/9

N2 - The Euclid mission is expected to image millions of galaxies at high resolution, providing an extensive dataset with which to study galaxy evolution. Because galaxy morphology is both a fundamental parameter and one that is hard to determine for large samples, we investigate the application of deep learning in predicting the detailed morphologies of galaxies in Euclid using Zoobot, a convolutional neural network pretrained with 450 000 galaxies from the Galaxy Zoo project. We adapted Zoobot for use with emulated Euclid images generated based on Hubble Space Telescope COSMOS images and with labels provided by volunteers in the Galaxy Zoo: Hubble project. We experimented with different numbers of galaxies and various magnitude cuts during the training process. We demonstrate that the trained Zoobot model successfully measures detailed galaxy morphology in emulated Euclid images. It effectively predicts whether a galaxy has features and identifies and characterises various features, such as spiral arms, clumps, bars, discs, and central bulges. When compared to volunteer classifications, Zoobot achieves mean vote fraction deviations of less than 12% and an accuracy of above 91% for the confident volunteer classifications across most morphology types. However, the performance varies depending on the specific morphological class. For the global classes, such as disc or smooth galaxies, the mean deviations are less than 10%, with only 1000 training galaxies necessary to reach this performance. On the other hand, for more detailed structures and complex tasks, such as detecting and counting spiral arms or clumps, the deviations are slightly higher, of namely around 12% with 60 000 galaxies used for training. In order to enhance the performance on complex morphologies, we anticipate that a larger pool of labelled galaxies is needed, which could be obtained using crowd sourcing. We estimate that, with our model, the detailed morphology of approximately 800 million galaxies of the Euclid Wide Survey could be reliably measured and that approximately 230 million of these galaxies would display features. Finally, our findings imply that the model can be effectively adapted to new morphological labels. We demonstrate this adaptability by applying Zoobot to peculiar galaxies. In summary, our trained Zoobot CNN can readily predict morphological catalogues for Euclid images.

AB - The Euclid mission is expected to image millions of galaxies at high resolution, providing an extensive dataset with which to study galaxy evolution. Because galaxy morphology is both a fundamental parameter and one that is hard to determine for large samples, we investigate the application of deep learning in predicting the detailed morphologies of galaxies in Euclid using Zoobot, a convolutional neural network pretrained with 450 000 galaxies from the Galaxy Zoo project. We adapted Zoobot for use with emulated Euclid images generated based on Hubble Space Telescope COSMOS images and with labels provided by volunteers in the Galaxy Zoo: Hubble project. We experimented with different numbers of galaxies and various magnitude cuts during the training process. We demonstrate that the trained Zoobot model successfully measures detailed galaxy morphology in emulated Euclid images. It effectively predicts whether a galaxy has features and identifies and characterises various features, such as spiral arms, clumps, bars, discs, and central bulges. When compared to volunteer classifications, Zoobot achieves mean vote fraction deviations of less than 12% and an accuracy of above 91% for the confident volunteer classifications across most morphology types. However, the performance varies depending on the specific morphological class. For the global classes, such as disc or smooth galaxies, the mean deviations are less than 10%, with only 1000 training galaxies necessary to reach this performance. On the other hand, for more detailed structures and complex tasks, such as detecting and counting spiral arms or clumps, the deviations are slightly higher, of namely around 12% with 60 000 galaxies used for training. In order to enhance the performance on complex morphologies, we anticipate that a larger pool of labelled galaxies is needed, which could be obtained using crowd sourcing. We estimate that, with our model, the detailed morphology of approximately 800 million galaxies of the Euclid Wide Survey could be reliably measured and that approximately 230 million of these galaxies would display features. Finally, our findings imply that the model can be effectively adapted to new morphological labels. We demonstrate this adaptability by applying Zoobot to peculiar galaxies. In summary, our trained Zoobot CNN can readily predict morphological catalogues for Euclid images.

U2 - 10.1051/0004-6361/202449609

DO - 10.1051/0004-6361/202449609

M3 - Article

SN - 0004-6361

VL - 689

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A274

ER -