Detection of Dipole Modulation in CMB Temperature Anisotropy Maps from WMAP and Planck using Artificial Intelligence

In this article, we employ a machine learning (ML) approach for the estimations of four fundamental parameters, namely, the Hubble constant (H0), matter (Ω0m), curvature (Ω0k) and vacuum (Ω0Λ) densities of non-flat ΛCDM model. We use 31 Hubble parameter values measured by differential ages (DA) technique in the redshift interval 0.07 ≤ z ≤ 1.965. We create an artificial neural network (ParamANN) and train it with simulated values of H(z) using various sets of H0, Ω0m, Ω0k, Ω0Λ parameters chosen from different and sufficiently wide prior intervals. We use a correlated noise model in the analysis. We demonstrate accurate validation and prediction using ParamANN. ParamANN provides an excellent cross-check for the validity of the ΛCDM model. We obtain H0 = 68.14 ± 3.96 kmMpc-1s-1, Ω0m = 0.3029 ± 0.1118, Ω0k = 0.0708 ± 0.2527 and Ω0Λ = 0.6258 ± 0.1689 by using the trained network. These parameter values agree very well with the results of global CMB observations of the Planck collaboration. We compare the cosmological parameter values predicted by ParamANN with those obtained by the MCMC method. Both the results agree well with each other. This demonstrates that ParamANN is an alternative and complementary approach to the well-known Metropolis-Hastings algorithm for estimating the cosmological parameters by using Hubble measurements.

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Probing cosmic homogeneity in the Local Universe

Dias,

Avila,

Bernui

2023

Monthly Notices of the Royal Astronomical Society

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We investigate the transition scale to homogeneity, RH, using as cosmic tracer the spectroscopic sample of blue galaxies from the Sloan Digital Sky Survey (SDSS). Considering the spatial distribution of the galaxy sample, we compute the two point correlation function ξ(r), the scaled counts in spheres $\mathcal {N}(\lt r)$, and the fractal dimension $\mathcal {D}_2(r)$ to quantify the homogeneity scale in the Local Universe (0.04 < z < 0.20). The sample in analysis is compared with random and mock catalogues with the same geometry, and the same number of synthetic cosmic objects as the data set, to calculate the covariance matrix for the errors determination. The criteria adopted for the transition-to-homogeneity follows the literature, it is attained when $\mathcal {D}_2(r)$ reaches the 1 per cent level of the limit value 3 (i.e. where it reaches 2.97) as the scale increases. We obtain RH = 70.33 ± 10.74 Mpc h−1, at the effective redshift zeff = 0.128, for a sample containing $150\, 302$ SDSS blue galaxies with 0.04 < z < 0.20. Additionally, we perform robustness tests by analysing the homogeneity scale in sub-volumes of the original one, obtaining coherent results; we also check for a possible artefact in our procedure examining a homogeneous synthetic data set as a pseudo-data, verifying that such systematic is absent. Because our analyses concentrate in data at low redshifts, z < 0.20, we find interesting to use cosmography to calculate the radial comoving distances; therefore in this subject our analyses do not use fiducial cosmological model. For completeness, we evaluate the difference of the comoving distances estimation using cosmography and fiducial cosmology.

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Detection of Dipole Modulation in CMB Temperature Anisotropy Maps from WMAP and Planck using Artificial Intelligence

Cited by 4 publications

References 84 publications

Reconstruction of full sky CMB E and B modes spectra removing E-to-B leakage from partial sky using deep learning

Reconstruction of full sky CMB E and B modes spectra removing E-to-B leakage from partial sky using deep learning

ParamANN: a neural network to estimate cosmological parameters for ΛCDM Universe using Hubble measurements

Probing cosmic homogeneity in the Local Universe

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