Deep learning for cosmological parameter inference from a dark matter halo density field

Abstract

We propose a lightweight deep convolutional neural network (lCNN) to estimate cosmological parameters from simulated three-dimensional dark matter (DM) halo distributions and associated statistics. The training dataset comprises 2000 realizations of a cubic box with a side length of 1000 h-1 Mpc, and interpolated over a cubic grid of 3003 voxels, with each simulation produced using 5123 DM particles and 5123 neutrinos. Under the flat model, simulations vary standard six cosmological parameters including m, b, h, ns, σ8, w, along with the neutrino mass sum, M. We find that: 1) within the framework of lCNN, extracting large-scale structure information is more efficient from the halo density field compared to relying on the statistical quantities including the power spectrum, the two-point correlation function, and the coefficients from wavelet scattering transform; 2) combining the halo density field with its Fourier transformed counterpart enhances predictions, while augmenting the training dataset with measured statistics further improves performance; 3) achieving high accuracy in inferring m, h, and σ8 by the neural network model, while being inefficient in predicting b, ns, M and w; 4) compared to the simple fully connected network trained with three statistical quantities, our CNN yields statistically reduced errors, showing improvements of approximately 23\% for m, 11\% for h, 8\% for ns, and 21\% for σ8. Additionally, in comparison with the likelihood-based analysis on P(k) data, our CNN provides much tighter constraints on parameters, especially on m and σ8. Our study emphasizes this lCNN-based novel approach in extracting large-scale structure information and estimating cosmological parameters.

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