Abstract
Weak lensing by large-scale structure is a powerful probe of cosmology and of the dark universe. This cosmic shear technique relies on the accurate measurement of the shapes and redshifts of background galaxies and requires precise control of systematic errors. The Monte Carlo Control Loops (MCCL) is a forward modelling method designed to tackle this problem. It relies on the Ultra Fast Image Generator (UFig) to produce simulated images tuned to match the target data statistically, followed by calibrations and tolerance loops. We present the first end-to-end application of this method, on the Dark Energy Survey (DES) Year 1 wide field imaging data. We simultaneously measure the shear power spectrum $C_{\ell}$ and the redshift distribution $n(z)$ of the background galaxy sample. The method includes maps of the systematic sources, Point Spread Function (PSF), an Approximate Bayesian Computation (ABC) inference of the simulation model parameters, a shear calibration scheme, and the fast estimation of the covariance matrix. We find a close statistical agreement between the simulations and the DES Y1 data using an array of diagnostics. In a non-tomographic setting, we derive a set of $C_\ell$ and $n(z)$ curves that encode the cosmic shear measurement, as well as the systematic uncertainty. Following a blinding scheme, we measure the combination of $\Omega_m$, $\sigma_8$, and intrinsic alignment amplitude $A_{\rm{IA}}$, defined as $S_8D_{\rm{IA}} = \sigma_8(\Omega_m/0.3)^{0.5}D_{\rm{IA}}$, where $D_{\rm{IA}}=1-0.11(A_{\rm{IA}}-1)$. We find $S_8D_{\rm{IA}}=0.895^{+0.054}_{-0.039}$, where systematics are at the level of roughly 60\% of the statistical errors. We discuss these results in the context of earlier cosmic shear analyses of the DES Y1 data. Our findings indicate that this method and its fast runtime offer good prospects for cosmic shear measurements with future wide-field surveys.
Highlights
Recent observations combining different cosmological probes have led to the establishment of the ΛCDM concordance model for cosmology
We find that the Dark Energy Survey (DES) histograms lie within the histograms measured from ultra fast image generator (UFig) simulations of approximate Bayesian computation (ABC) posterior
We define the following set of quality conditions to be met by our measurement before unblinding: (Q1) properties of the DES galaxy population have to lie within the space covered by the simulations, (Q2) for the fiducial simulation, the input cosmology should be accurately recovered, (Q3) the impact of the possible discrepancies in systematic maps can not be larger than the statistical errors on the measurement, (Q4) small shear B-mode and small cross power spectra between shear and point spread function (PSF), and (Q5) analysis versions that include well-motivated extensions to the model should not cause significant difference in final result
Summary
Recent observations combining different cosmological probes have led to the establishment of the ΛCDM concordance model for cosmology. The Monte Carlo control loop [17] (MCCL) method was proposed to tackle the shear and nðzÞ measurement jointly It is based on a forward modeling approach using the ultra fast image generator (UFig) [18]. In this method, image simulations are first tuned to agree statistically with the target data set and used to calibrate the cosmic shear measurement and to quantify its systematic uncertainty. We present the first end-to-end cosmological analysis using the MCCL method, applied to the DES Year 1 (Y1) survey It constitutes a nontomographic reanalysis of this data set with an independent approach. The appendix describes our blinding scheme, the PSF modeling, the implementation of approximate Bayesian computation (ABC), and the internal tests on simulations
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