Emulation of Cosmological Mass Maps with Conditional Generative Adversarial Networks

Perraudin, Nathanaël; Marcon, Sandro; Lucchi, Aurélien; Kacprzak, T.

doi:10.3389/frai.2021.673062

Cited by 8 publications

(8 citation statements)

References 43 publications

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“…This architecture has shown to produce 2D and 3D fields quantitatively very similar to those obtained by direct numerical simulation (Rodrı ´guez et al 2018;Perraudin et al 2019;Tamosiunas et al 2021;Ullmo et al 2020;Feder et al 2020), even in previously unseen cosmologies (see Fig. 28 and Perraudin et al 2021). The architectures used to create fake data can also be combined with existing data from, for instance, low resolution simulations to artificially increase their resolution.…”

Section: Machine Learningsupporting

confidence: 73%

“…In this case, the GAN was trained with 46 different combinations of cosmological parameters (X m and r 8 ), and we can see it is able to generate data that correctly captures the cosmological dependence of such maps. Image adapted from Perraudin et al (2021), copyright by the authors uncertainty in the data analysis, for which it will be very important to accurately quantify the emulator uncertainty in the first place. This will be a challenge per se since these are typically empirically measured with a small number of simulations.…”

Section: Emulators and Interpolatorsmentioning

confidence: 99%

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Large-scale dark matter simulations

Angulo

Hahn

2022

Living Rev Comput Astrophys

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We review the field of collisionless numerical simulations for the large-scale structure of the Universe. We start by providing the main set of equations solved by these simulations and their connection with General Relativity. We then recap the relevant numerical approaches: discretization of the phase-space distribution (focusing on N-body but including alternatives, e.g., Lagrangian submanifold and Schrödinger–Poisson) and the respective techniques for their time evolution and force calculation (direct summation, mesh techniques, and hierarchical tree methods). We pay attention to the creation of initial conditions and the connection with Lagrangian Perturbation Theory. We then discuss the possible alternatives in terms of the micro-physical properties of dark matter (e.g., neutralinos, warm dark matter, QCD axions, Bose–Einstein condensates, and primordial black holes), and extensions to account for multiple fluids (baryons and neutrinos), primordial non-Gaussianity and modified gravity. We continue by discussing challenges involved in achieving highly accurate predictions. A key aspect of cosmological simulations is the connection to cosmological observables, we discuss various techniques in this regard: structure finding, galaxy formation and baryonic modelling, the creation of emulators and light-cones, and the role of machine learning. We finalise with a recount of state-of-the-art large-scale simulations and conclude with an outlook for the next decade.

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Section: Machine Learningsupporting

confidence: 73%

Section: Emulators and Interpolatorsmentioning

confidence: 99%

Large-scale dark matter simulations

Angulo

Hahn

2022

Living Rev Comput Astrophys

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“…The GAN model proposed in Feder et al (2020) was for instance made conditional on redshift by simple concatenation of the conditional variable to the latent vector of the GAN, allowing the authors to generate volumes at intermediate redshifts, which would be useful to create lightcones. Perraudin et al (2020) proposed a conditional GANs to produce 2D weak-lensing mass-maps conditioned on (σ 8 , m ) through a remapping of the latent vector of the GAN by a function that rescales the norm of that vector based on the conditional variable. More recently, Wing Hei Yiu, Fluri, & Kacprzak (2021) extended that work to the sphere, using a DeepSphere (Perraudin et al 2019b) graph convolutional architecture, to emulate the KiDS-1000 survey footprint as a function of (σ 8 , m ).…”

Section: N-body Emulation By Deep Generative Modellingmentioning

confidence: 99%

The Dawes Review 10: The impact of deep learning for the analysis of galaxy surveys

Huertas-Company

Lanusse²

2023

Publ. Astron. Soc. Aust.

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The amount and complexity of data delivered by modern galaxy surveys has been steadily increasing over the past years. New facilities will soon provide imaging and spectra of hundreds of millions of galaxies. Extracting coherent scientific information from these large and multi-modal data sets remains an open issue for the community and data-driven approaches such as deep learning have rapidly emerged as a potentially powerful solution to some long lasting challenges. This enthusiasm is reflected in an unprecedented exponential growth of publications using neural networks, which have gone from a handful of works in 2015 to an average of one paper per week in 2021 in the area of galaxy surveys. Half a decade after the first published work in astronomy mentioning deep learning, and shortly before new big data sets such as Euclid and LSST start becoming available, we believe it is timely to review what has been the real impact of this new technology in the field and its potential to solve key challenges raised by the size and complexity of the new datasets. The purpose of this review is thus two-fold. We first aim at summarising, in a common document, the main applications of deep learning for galaxy surveys that have emerged so far. We then extract the major achievements and lessons learned and highlight key open questions and limitations, which in our opinion, will require particular attention in the coming years. Overall, state-of-the-art deep learning methods are rapidly adopted by the astronomical community, reflecting a democratisation of these methods. This review shows that the majority of works using deep learning up to date are oriented to computer vision tasks (e.g. classification, segmentation). This is also the domain of application where deep learning has brought the most important breakthroughs so far. However, we also report that the applications are becoming more diverse and deep learning is used for estimating galaxy properties, identifying outliers or constraining the cosmological model. Most of these works remain at the exploratory level though which could partially explain the limited impact in terms of citations. Some common challenges will most likely need to be addressed before moving to the next phase of massive deployment of deep learning in the processing of future surveys; for example, uncertainty quantification, interpretability, data labelling and domain shift issues from training with simulations, which constitutes a common practice in astronomy.

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“…image-to-image translation [12] or image editing [8,32,38,39]. The computational power of (conditional) GANs has already found its way to physics, starting in high energy physics for the simulation of 2D particle jet images [40] and 3D particle showers [41], cosmology for emulations of cosmological maps [42], and in selected problems of quantum and condensed matter physics including the simulation of correlated Quantum Walk [28] and to simulate 2D Ising model near the critical temperature [29]. Recently, conditional GANs have also been successfully applied for quantum state tomography and the reconstruction of density matrices [30].…”

Section: A Generative Adversarial Networkmentioning

confidence: 99%

Designing quantum many-body matter with conditional generative adversarial networks

Koch¹,

Lado²

2022

Preprint

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The computation of dynamical correlators of quantum many-body systems represents an open critical challenge in condensed matter physics. While powerful methodologies have risen in recent years, covering the full parameter space remains unfeasible for most many-body systems with a complex configuration space. Here we demonstrate that conditional Generative Adversarial Networks (GANs) allow simulating the full parameter space of several many-body systems, accounting both for controlled parameters, and stochastic disorder effects. After training with a restricted set of noisy many-body calculations, the conditional GAN algorithm provides the whole dynamical excitation spectra for a Hamiltonian instantly and with an accuracy analogous to the exact calculation. We further demonstrate how the trained conditional GAN automatically provides a powerful method for Hamiltonian learning from its dynamical excitations, and to flag non-physical systems via outlier detection. Our methodology puts forward generative adversarial learning as a powerful technique to explore complex many-body phenomena, providing a starting point to design large-scale quantum many-body matter.

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Emulation of Cosmological Mass Maps with Conditional Generative Adversarial Networks

Cited by 8 publications

References 43 publications

Large-scale dark matter simulations

Large-scale dark matter simulations

The Dawes Review 10: The impact of deep learning for the analysis of galaxy surveys

Designing quantum many-body matter with conditional generative adversarial networks

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