Rubin-LSST

LyaCoLoRe: Synthetic Datasets for Current and Future Lyman-${\alpha}$ Forest BAO Surveys

(2019)

Authors:

James Farr, Andreu Font-Ribera, Hélion du Mas des Bourboux, Andrea Muñoz-Gutiérrez, Francisco Javier Sanchez Lopez, Andrew Pontzen, Alma Xochitl González-Morales, David Alonso, David Brooks, Peter Doel, Thomas Etourneau, Julien Guy, Jean-Marc Le Goff, Axel de al Macorra, Nathalie Palanque-Delabrouille, Ignasi Pérez-Ràfols, James Rich, Anže Slosar, Gregory Tarle, Duan Yutong, Kai Zhang

KiDS-SQuaD

Astronomy & Astrophysics EDP Sciences 632 (2019) a56

Authors:

Vladislav Khramtsov, Alexey Sergeyev, Chiara Spiniello, Crescenzo Tortora, Nicola R Napolitano, Adriano Agnello, Fedor Getman, Jelte TA de Jong, Konrad Kuijken, Mario Radovich, HuanYuan Shan, Valery Shulga

Report on Status of ESO Public Surveys and Current Activities

The Messenger 178 (2019) 10-16

Authors:

M Arnaboldi, N Delmotte, D Gadotti, M Hilker, G Hussain, L Mascetti, A Micol, M Petr-Gotzens, M Rejkuba, J Retzlaff, C Spiniello, B Leibundgut, M Romaniello

Disconnected pseudo-Cℓ covariances for projected large-scale structure data

Journal of Cosmology and Astroparticle Physics IOP Publishing 2019:11 (2019) 043-043

Authors:

Carlos García-García, David Alonso, Emilio Bellini

Disconnected pseudo-Cℓ covariances for projected large-scale structure data

Journal of Cosmology and Astroparticle Physics IOP Publishing 2019:11 (2019) 043

Authors:

C García-García, D Alonso, Emilio Bellini

Abstract:

The disconnected part of the power spectrum covariance matrix (also known as the "Gaussian" covariance) is the dominant contribution on large scales for galaxy clustering and weak lensing datasets. The presence of a complicated sky mask causes non-trivial correlations between different Fourier/harmonic modes, which must be accurately characterized in order to obtain reliable cosmological constraints. This is particularly relevant for galaxy survey data. Unfortunately, an exact calculation of these correlations involves O(ℓmax6) operations that become computationally impractical very quickly. We present an implementation of approximate methods to estimate the Gaussian covariance matrix of power spectra involving spin-0 and spin-2 flat- and curved-sky fields, expanding on existing algorithms {developed in the context of CMB analyses}. These methods achieve an O(ℓmax3) scaling, which makes the computation of the covariance matrix as fast as the computation of the power spectrum itself. We quantify the accuracy of these methods on large-scale structure and weak lensing data, making use of a large number of Gaussian but otherwise realistic simulations. We show that, using the approximate covariance matrix, we are able to recover the true posterior distribution of cosmological parameters to high accuracy. We also quantify the shortcomings of these methods, which become unreliable on the very largest scales, as well as for covariance matrix elements involving cosmic shear B modes. The algorithms presented here are implemented in the public code NaMaster https://github.com/LSSTDESC/NaMaster.