CosmoGridV1: a simulated \(w\)CDM theory prediction for map-level cosmological inference

We present CosmoGridV1: a large set of lightcone simulations for map-level cosmological inference with probes of large scale structure. It is designed for cosmological parameter measurement based on Stage-III photometric surveys with non-Gaussian statistics and machine learning. CosmoGridV1 spans th...

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Bibliographic Details
Published inarXiv.org
Main Authors Kacprzak, Tomasz, Fluri, Janis, Schneider, Aurel, Refregier, Alexandre, Stadel, Joachim
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 14.11.2022
Subjects
Astronomical maps
Baryons
Clustering
Cosmology
Deep learning
Gravitational lenses
Inference
Large scale structure of the universe
Machine learning
Neutrinos
Red shift
Simulation
Sky surveys (astronomy)
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Summary:We present CosmoGridV1: a large set of lightcone simulations for map-level cosmological inference with probes of large scale structure. It is designed for cosmological parameter measurement based on Stage-III photometric surveys with non-Gaussian statistics and machine learning. CosmoGridV1 spans the \(w\)CDM model by varying \(\Omega_m\), \(\sigma_8\), \(w_0\), \(H_0\), \(n_s\), \(\Omega_b\), and assumes three degenerate neutrinos with \(\sum m_\nu\) = 0.06 eV. This space is covered by 2500 grid points on a Sobol sequence. At each grid point, we run 7 simulations with PkdGrav3 and store 69 particle maps at nside=2048 up to \(z\)=3.5, as well as halo catalog snapshots. The fiducial cosmology has 200 independent simulations, along with their stencil derivatives. An important part of CosmoGridV1 is the benchmark set of 28 simulations, which include larger boxes, higher particle counts, and higher redshift resolution of shells. They allow for testing if new types of analyses are sensitive to choices made in CosmoGridV1. We add baryon feedback effects on the map level, using shell-based baryon correction model. The shells are used to create maps of weak gravitational lensing, intrinsic alignment, and galaxy clustering, using the UFalcon code. The main part of CosmoGridV1 are the raw particle count shells that can be used to create full-sky maps for a given \(n(z)\). We also release projected maps for a Stage-III forecast, as well as maps used previously in KiDS-1000 deep learning constraints with CosmoGridV1. The data is available at www.cosmogrid.ai.
ISSN:2331-8422
DOI:10.48550/arxiv.2209.04662