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Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration

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Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration . / Euclid Collaboration.
In: Astronomy and Astrophysics, Vol. 695, A283, 31.03.2025.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Euclid Collaboration 2025, 'Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration ', Astronomy and Astrophysics, vol. 695, A283. https://doi.org/10.1051/0004-6361/202452129

APA

Euclid Collaboration (2025). Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration . Astronomy and Astrophysics, 695, Article A283. https://doi.org/10.1051/0004-6361/202452129

Vancouver

Euclid Collaboration. Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration . Astronomy and Astrophysics. 2025 Mar 31;695:A283. doi: 10.1051/0004-6361/202452129

Author

Euclid Collaboration. / Euclid preparation  : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration . In: Astronomy and Astrophysics. 2025 ; Vol. 695.

Bibtex

@article{30d71c1ae44947849e3dfbd9b4571651,
title = "Euclid preparation : LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration ",
abstract = "To date, galaxy image simulations for weak lensing surveys usually approximate the light profiles of all galaxies as a single or double S{\'e}rsic profile, neglecting the influence of galaxy substructures and morphologies deviating from such a simplified parametric characterisation. While this approximation may be sufficient for previous data sets, the stringent cosmic shear calibration requirements and the high quality of the data in the upcoming Euclid survey demand a consideration of the effects that realistic galaxy substructures and irregular shapes have on shear measurement biases. Here we present a novel deep learning-based method to create such simulated galaxies directly from Hubble Space Telescope (HST) data. We first build and validate a convolutional neural network based on the wavelet scattering transform to learn noise-free representations independent of the point-spread function (PSF) of HST galaxy images. These can be injected into simulations of images from Euclid{\textquoteright}s optical instrument VIS without introducing noise correlations during PSF convolution or shearing. Then, we demonstrate the generation of new galaxy images by sampling from the model randomly as well as conditionally. In the latter case, we fine-tune the interpolation between latent space vectors of sample galaxies to directly obtain new realistic objects following a specific S{\'e}rsic index and half-light radius distribution. Furthermore, we show that the distribution of galaxy structural and morphological parameters of our generative model matches the distribution of the input HST training data, proving the capability of the model to produce realistic shapes. Next, we quantify the cosmic shear bias from complex galaxy shapes in Euclid-like simulations by comparing the shear measurement biases between a sample of model objects and their best-fit double-S{\'e}rsic counterparts, thereby creating two separate branches that only differ in the complexity of their shapes. Using the Kaiser, Squires, and Broadhurst shape measurement algorithm, we find a multiplicative bias difference between these branches with realistic morphologies and parametric profiles on the order of (6.9 ± 0.6)×10−3 for a realistic magnitude-S{\'e}rsic index distribution. Moreover, we find clear detection bias differences between full image scenes simulated with parametric and realistic galaxies, leading to a bias difference of (4.0 ± 0.9)×10−3 independent of the shape measurement method. This makes complex morphology relevant for stage IV weak lensing surveys, exceeding the full error budget of the Euclid Wide Survey (Δμ1, 2 < 2 × 103).",
author = "{Euclid Collaboration} and B. Csizi and T. Schrabback and S. Grandis and H. Hoekstra and H. Jansen and L. Linke and G. Congedo and Taylor, {A. N.} and A. Amara and S. Andreon and C. Baccigalupi and M. Baldi and S. Bardelli and P. Battaglia 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 Castander, {F. J.} and M. Castellano and G. Castignani and S. Cavuoti and A. Cimatti and C. Colodro-Conde and Conselice, {C. J.} and L. Conversi and Y. Copin and F. Courbin and Courtois, {H. M.} and M. Cropper and {Da Silva}, A. and H. Degaudenzi and {De Lucia}, G. and J. Dinis and M. Douspis and I. Hook and Y. Wang and J. Weller and Ferrari, {A. G.} and A. Hall and A. Mora and D. Potter and C. Tao",
year = "2025",
month = mar,
day = "31",
doi = "10.1051/0004-6361/202452129",
language = "English",
volume = "695",
journal = "Astronomy and Astrophysics",
issn = "0004-6361",
publisher = "EDP Sciences",

}

RIS

TY - JOUR

T1 - Euclid preparation 

T2 - LXVII. Deep learning true galaxy morphologies for weak lensing shear bias calibration

AU - Euclid Collaboration

AU - Csizi, B.

AU - Schrabback, T.

AU - Grandis, S.

AU - Hoekstra, H.

AU - Jansen, H.

AU - Linke, L.

AU - Congedo, G.

AU - Taylor, A. N.

AU - Amara, A.

AU - Andreon, S.

AU - Baccigalupi, C.

AU - Baldi, M.

AU - Bardelli, S.

AU - Battaglia, P.

AU - Bender, R.

AU - Bodendorf, C.

AU - Bonino, D.

AU - Branchini, E.

AU - Brescia, M.

AU - Brinchmann, J.

AU - Camera, S.

AU - Capobianco, V.

AU - Carbone, C.

AU - Carretero, J.

AU - Casas, S.

AU - Castander, F. J.

AU - Castellano, M.

AU - Castignani, G.

AU - Cavuoti, S.

AU - Cimatti, A.

AU - Colodro-Conde, C.

AU - Conselice, C. J.

AU - Conversi, L.

AU - Copin, Y.

AU - Courbin, F.

AU - Courtois, H. M.

AU - Cropper, M.

AU - Da Silva, A.

AU - Degaudenzi, H.

AU - De Lucia, G.

AU - Dinis, J.

AU - Douspis, M.

AU - Hook, I.

AU - Wang, Y.

AU - Weller, J.

AU - Ferrari, A. G.

AU - Hall, A.

AU - Mora, A.

AU - Potter, D.

AU - Tao, C.

PY - 2025/3/31

Y1 - 2025/3/31

N2 - To date, galaxy image simulations for weak lensing surveys usually approximate the light profiles of all galaxies as a single or double Sérsic profile, neglecting the influence of galaxy substructures and morphologies deviating from such a simplified parametric characterisation. While this approximation may be sufficient for previous data sets, the stringent cosmic shear calibration requirements and the high quality of the data in the upcoming Euclid survey demand a consideration of the effects that realistic galaxy substructures and irregular shapes have on shear measurement biases. Here we present a novel deep learning-based method to create such simulated galaxies directly from Hubble Space Telescope (HST) data. We first build and validate a convolutional neural network based on the wavelet scattering transform to learn noise-free representations independent of the point-spread function (PSF) of HST galaxy images. These can be injected into simulations of images from Euclid’s optical instrument VIS without introducing noise correlations during PSF convolution or shearing. Then, we demonstrate the generation of new galaxy images by sampling from the model randomly as well as conditionally. In the latter case, we fine-tune the interpolation between latent space vectors of sample galaxies to directly obtain new realistic objects following a specific Sérsic index and half-light radius distribution. Furthermore, we show that the distribution of galaxy structural and morphological parameters of our generative model matches the distribution of the input HST training data, proving the capability of the model to produce realistic shapes. Next, we quantify the cosmic shear bias from complex galaxy shapes in Euclid-like simulations by comparing the shear measurement biases between a sample of model objects and their best-fit double-Sérsic counterparts, thereby creating two separate branches that only differ in the complexity of their shapes. Using the Kaiser, Squires, and Broadhurst shape measurement algorithm, we find a multiplicative bias difference between these branches with realistic morphologies and parametric profiles on the order of (6.9 ± 0.6)×10−3 for a realistic magnitude-Sérsic index distribution. Moreover, we find clear detection bias differences between full image scenes simulated with parametric and realistic galaxies, leading to a bias difference of (4.0 ± 0.9)×10−3 independent of the shape measurement method. This makes complex morphology relevant for stage IV weak lensing surveys, exceeding the full error budget of the Euclid Wide Survey (Δμ1, 2 < 2 × 103).

AB - To date, galaxy image simulations for weak lensing surveys usually approximate the light profiles of all galaxies as a single or double Sérsic profile, neglecting the influence of galaxy substructures and morphologies deviating from such a simplified parametric characterisation. While this approximation may be sufficient for previous data sets, the stringent cosmic shear calibration requirements and the high quality of the data in the upcoming Euclid survey demand a consideration of the effects that realistic galaxy substructures and irregular shapes have on shear measurement biases. Here we present a novel deep learning-based method to create such simulated galaxies directly from Hubble Space Telescope (HST) data. We first build and validate a convolutional neural network based on the wavelet scattering transform to learn noise-free representations independent of the point-spread function (PSF) of HST galaxy images. These can be injected into simulations of images from Euclid’s optical instrument VIS without introducing noise correlations during PSF convolution or shearing. Then, we demonstrate the generation of new galaxy images by sampling from the model randomly as well as conditionally. In the latter case, we fine-tune the interpolation between latent space vectors of sample galaxies to directly obtain new realistic objects following a specific Sérsic index and half-light radius distribution. Furthermore, we show that the distribution of galaxy structural and morphological parameters of our generative model matches the distribution of the input HST training data, proving the capability of the model to produce realistic shapes. Next, we quantify the cosmic shear bias from complex galaxy shapes in Euclid-like simulations by comparing the shear measurement biases between a sample of model objects and their best-fit double-Sérsic counterparts, thereby creating two separate branches that only differ in the complexity of their shapes. Using the Kaiser, Squires, and Broadhurst shape measurement algorithm, we find a multiplicative bias difference between these branches with realistic morphologies and parametric profiles on the order of (6.9 ± 0.6)×10−3 for a realistic magnitude-Sérsic index distribution. Moreover, we find clear detection bias differences between full image scenes simulated with parametric and realistic galaxies, leading to a bias difference of (4.0 ± 0.9)×10−3 independent of the shape measurement method. This makes complex morphology relevant for stage IV weak lensing surveys, exceeding the full error budget of the Euclid Wide Survey (Δμ1, 2 < 2 × 103).

U2 - 10.1051/0004-6361/202452129

DO - 10.1051/0004-6361/202452129

M3 - Journal article

VL - 695

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

SN - 0004-6361

M1 - A283

ER -