2023
DOI: 10.3847/1538-4357/aca7c2
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A Framework for Obtaining Accurate Posteriors of Strong Gravitational Lensing Parameters with Flexible Priors and Implicit Likelihoods Using Density Estimation

Abstract: 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 e… Show more

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Cited by 9 publications
(5 citation statements)
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“…It is important to note that because SLIC learns the distribution of noise in the entirety of the data space, it maintains the complete information content of the data during inference. Therefore, when compared to simulation-based inference methods that resort to data compression techniques in which may lose information (Cranmer et al 2020;Legin et al 2023), SLIC is expected to provide equal (if the compression is optimal) or greater precision during inference.…”
Section: Discussionmentioning
confidence: 99%
“…It is important to note that because SLIC learns the distribution of noise in the entirety of the data space, it maintains the complete information content of the data during inference. Therefore, when compared to simulation-based inference methods that resort to data compression techniques in which may lose information (Cranmer et al 2020;Legin et al 2023), SLIC is expected to provide equal (if the compression is optimal) or greater precision during inference.…”
Section: Discussionmentioning
confidence: 99%
“…We then estimate the posterior distribution of model parameters conditioned on an ensemble of observations, with results shown in Figure 19. Using a procedure similar to Hahn & Melchior (2022) and related papers (Khullar et al 2022;Legin et al 2023;Lemos et al 2023;Wang et al 2023), we implement SBI combined with amortized neural posterior estimation to determine that ensemble observations of about 30 galaxies allow us to constrain the timescales and scatter enough to differentiate between the toy models in this paper. Adding additional systematics like variable metallicity or observational noise broadens the posteriors, but nevertheless allows us to distinguish between the toy models and obtain constraints on the timescales, as shown in Figure 20.…”
Section: Appendix E Observational Constraints On Timescales Using Sim...mentioning
confidence: 99%
“…When allocated one node (32 CPU threads) on highperformance computing clusters, our current nested sampling infrastructure sees typical per-target timescales on the order of a week. As such, our future work will instead rely on the development of a simulation-based inference (SBI; Cranmer et al 2020) machine-learning infrastructure; these have seen great success in recent years (see Alsing et al 2018Alsing et al , 2019Miller et al 2020;Tejero-Cantero et al 2020;Miller et al 2022;Legin et al 2023b). The amortized nature of SBI will allow for computationally efficient deployment across parameter space in catalog-wide applications to current and future missions (Kepler,K2,TESS,PLATO,etc.…”
Section: Next Stepsmentioning
confidence: 99%