About: Magrathea-Pathfinder: a 3D adaptive-mesh code for geodesic ray tracing in N-body simulations

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Attributs	Valeurs
type	work Article
Is Part Of	http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/w
Subject	Numerical methods and codes gravitational lensing: weak methods: numerical gravitation large-scale structure of Universe
License	https://www.edpsciences.org/
Title	Magrathea-Pathfinder: a 3D adaptive-mesh code for geodesic ray tracing in N-body simulations
Date	2022-01-01(xsd:dateTime)
has manifestation of work	http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/aa42661-21/m/print http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/aa42661-21/m/web
related by	http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/aa42661-21/authorship/2 http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/aa42661-21/authorship/1
Author	Reverdy, Vincent Breton, Michel-Andrès Reverdy, Vincent Breton, Michel-Andrès
Abstract	We introduce M AGRATHEA-P ATHFINDER, a relativistic ray-tracing framework that can reconstruct the past light cone of observers in cosmological simulations. The code directly computes the 3D trajectory of light rays through the null geodesic equations, with the weak-field limit as its only approximation. This approach offers high levels of versatility while removing the need for many of the standard ray-tracing approximations such as plane-parallel, Born, or multiple-lens. Moreover, the use of adaptive integration steps and interpolation strategies based on adaptive-mesh refinement grids allows M AGRATHEA-P ATHFINDER to accurately account for the nonlinear regime of structure formation and fully take advantage of the small-scale gravitational clustering. To handle very large N-body simulations, the framework has been designed as a high-performance computing post-processing tool relying on a hybrid paralleliza-tion that combines MPI tasks with C++11 std::threads. In this paper, we describe how realistic cosmological observables can be computed from numerical simulation using ray-tracing techniques. We discuss in particular the production of simulated catalogues and sky maps that account for all the observational effects considering first-order metric perturbations (such as peculiar velocities, gravitational potential, integrated Sachs-Wolfe, time-delay, and gravitational lensing). We perform convergence tests of our gravitational lensing algorithms and conduct performance benchmarks of the null geodesic integration procedures. M AGRATHEA-P ATHFINDER introduces sophisticated ray-tracing tools to make the link between the space of N-body simulations and light-cone observables. This should provide new ways of exploring existing cosmological probes and building new ones beyond standard assumptions in order to prepare for the next generation of large-scale structure surveys.
article type	research-article
publisher identifier	aa42661-21
Date Copyrighted	2022-01-01(xsd:dateTime)
Rights	© M.-A. Breton and V. Reverdy 2022
Rights Holder	M.-A. Breton and V. Reverdy
is part of this journal	Astronomy & Astrophysics
is primary topic of	http://hub.abes.fr/edp/periodical/aa/2022/volume_662/issue_2022/aa42661-21/w/record

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