Posterior samples of source galaxies in strong gravitational lenses with score-based priors

Adam, Alexandre; Coogan, Adam; Malkin, Nikolay; Legin, Ronan; Perreault-Levasseur, Laurence; Hezaveh, Yashar; Bengio, Yoshua

doi:10.48550/arxiv.2211.03812

Cited by 7 publications

(3 citation statements)

References 22 publications

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“…One possibility for circumventing this issue is to have a separate approximate inference of the nuisance parameters and draw the simulations for the density estimation stage from these posteriors. This may be possible in a scenario where a separate network is trained to infer a posterior distribution for the nuisance parameters (e.g., a generative model for the background source conditioned on the data; see Adam et al 2022aAdam et al , 2022b. As mentioned earlier, alternative implicit likelihood inference frameworks that allow implicit marginalization over nuisance parameters (e.g., likelihood ratio methods) are generally only practical in low-dimensional spaces.…”

Section: Discussionmentioning

confidence: 99%

A Framework for Obtaining Accurate Posteriors of Strong Gravitational Lensing Parameters with Flexible Priors and Implicit Likelihoods Using Density Estimation

Legin

Hezaveh

Perreault-Levasseur

et al. 2023

ApJ

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We report the application of implicit likelihood inference to the prediction of the macroparameters of strong lensing systems with neural networks. This allows us to perform deep-learning analysis of lensing systems within a well-defined Bayesian statistical framework to explicitly impose desired priors on lensing variables, obtain accurate posteriors, and guarantee convergence to the optimal posterior in the limit of perfect performance. We train neural networks to perform a regression task to produce point estimates of lensing parameters. We then interpret these estimates as compressed statistics in our inference setup and model their likelihood function using mixture density networks. We compare our results with those of approximate Bayesian neural networks, discuss their significance, and point to future directions. Based on a test set of 100,000 strong lensing simulations, our amortized model produces accurate posteriors for any arbitrary confidence interval, with a maximum percentage deviation of 1.4% at the 21.8% confidence level, without the need for any added calibration procedure. In total, inferring 100,000 different posteriors takes a day on a single GPU, showing that the method scales well to the thousands of lenses expected to be discovered by upcoming sky surveys.

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Section: Discussionmentioning

confidence: 99%

A Framework for Obtaining Accurate Posteriors of Strong Gravitational Lensing Parameters with Flexible Priors and Implicit Likelihoods Using Density Estimation

Legin

Hezaveh

Perreault-Levasseur

et al. 2023

ApJ

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“…Perhaps the most important limitation of the method is the fact that, in its current form, the model only provides point estimates of the parameters of interest. Quantifying the posteriors of such high-dimensional data will require an efficient and accurate generative process (e.g., see Adam et al 2022), which we plan to explore and develop in future works.…”

Section: Discussionmentioning

confidence: 99%

Pixelated Reconstruction of Foreground Density and Background Surface Brightness in Gravitational Lensing Systems Using Recurrent Inference Machines

Adam

Perreault-Levasseur

Hezaveh

et al. 2023

ApJ

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Modeling strong gravitational lenses in order to quantify distortions in the images of background sources and to reconstruct the mass density in foreground lenses has been a difficult computational challenge. As the quality of gravitational lens images increases, the task of fully exploiting the information they contain becomes computationally and algorithmically more difficult. In this work, we use a neural network based on the recurrent inference machine to reconstruct simultaneously an undistorted image of the background source and the lens mass density distribution as pixelated maps. The method iteratively reconstructs the model parameters (the image of the source and a pixelated density map) by learning the process of optimizing the likelihood given the data using the physical model (a ray-tracing simulation), regularized by a prior implicitly learned by the neural network through its training data. When compared to more traditional parametric models, the proposed method is significantly more expressive and can reconstruct complex mass distributions, which we demonstrate by using realistic lensing galaxies taken from the IllustrisTNG cosmological hydrodynamic simulation.

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“…However, analyzing such unprecedentedly large samples will also pose a computational challenge. One way to tackle this challenge is to use machine learning for lensing parameter extraction from the data, which is currently an active area of research (e.g., Hezaveh et al 2017;Morningstar et al 2019;Schuldt et al 2021;Adam et al 2022;Poh et al 2022;Mishra-Sharma and Yang 2022;Biggio et al 2023). However, depending on specific scientific requirements, the conventional forward modeling approach would still be favorable for a subset of all the new lenses.…”

Section: Future Prospects In the Era Of Big Datamentioning

confidence: 99%

Strong Lensing by Galaxies: Past Highlights, Current Status, and Future Prospects

Shajib

2022

Proc. IAU

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Galaxy-scale strong lensing is a powerful tool in Astrophysics and Cosmology, enabling studies of massive galaxies’ internal structure, their formation and evolution, stellar initial mass function, and cosmological parameters. In this conference proceeding, we highlight key findings from the past decade in astrophysical applications of strong lensing at the galaxy scale. We then briefly summarize the present status of discovery and analyses of new samples from recent or ongoing surveys. Finally, we offer insights into anticipated developments in the upcoming era of big data shaping the future of this field, thanks to the Rubin, Euclid, and Roman observatories.

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Posterior samples of source galaxies in strong gravitational lenses with score-based priors

Cited by 7 publications

References 22 publications

A Framework for Obtaining Accurate Posteriors of Strong Gravitational Lensing Parameters with Flexible Priors and Implicit Likelihoods Using Density Estimation

A Framework for Obtaining Accurate Posteriors of Strong Gravitational Lensing Parameters with Flexible Priors and Implicit Likelihoods Using Density Estimation

Pixelated Reconstruction of Foreground Density and Background Surface Brightness in Gravitational Lensing Systems Using Recurrent Inference Machines

Strong Lensing by Galaxies: Past Highlights, Current Status, and Future Prospects

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