Euclid: The linear-construction covariance and cosmology

Abstract

We study the properties of galaxy cluster 2-point correlation function covariance matrices estimated using the linear-construction (LC) method, which is computationally up to 20 times faster than the standard sample-covariance method. Our goal is to assess how well the LC method performs in cosmological parameter estimation compared to the sample covariance. We use a set of 1000 mock dark matter halo catalogues to compute both the LC-covariance and the sample-covariance estimates in four redshift shells. These numerical matrices are used to fit a theoretical four-parameter model for the covariance. We then use the two fitted covariance models in a likelihood function to estimate two cosmological parameters - the matter density parameter m and the amplitude of the matter density fluctuations σ8 - from the simulated mock catalogues. The purpose of this is to validate the LC-covariance-based model against the sample-covariance model. The catalogues were simulated assuming the spatially flat cosmology, with m = 0.30711 and σ8=0.8288. We find that the parameter posteriors obtained using the sample- and LC-covariance models agree well with each other and with the simulation cosmology. The two pairs of marginalized constraints are m = 0.307 0.003 and σ8 = 0.826 0.009 (sample covariance), and m = 0.308 0.003 and σ8 = 0.825 0.009 (LC covariance). The posterior widths are the same, and the difference in the median values is less than 0.16\,σ for both parameters.

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