We develop a deep learning technique to infer the non-linear velocity field from the dark matter density field. The deep learning architecture we use is an "U-net" style convolutional neural network, which consists of 15 convolution layers and 2 deconvolution layers. This setup maps the 3-dimensional density field of 323-voxels to the 3-dimensional velocity or momentum fields of 203-voxels. Through the analysis of the dark matter simulation with a resolution of 2h−1Mpc, we find that the network can predict the the non-linearity, complexity and vorticity of the velocity and momentum fields, as well as the power spectra of their value, divergence and vorticity and its prediction accuracy reaches the range of k≃1.4hMpc−1 with a relative error ranging from 1% to ≲10%. A simple comparison shows that neural networks may have an overwhelming advantage over perturbation theory in the reconstruction of velocity or momentum fields.
@article{arxiv.2105.09450,
title = {Cosmic Velocity Field Reconstruction Using AI},
author = {Ziyong Wu and Zhenyu Zhang and Shuyang Pan and Haitao Miao and Xin Wang and Cristiano G. Sabiu and Jaime Forero-Romero and Yang Wang and Xiao-Dong Li},
journal= {arXiv preprint arXiv:2105.09450},
year = {2021}
}
Comments
10 pages, 6 figures, 4 tables, accepted for publication in ApJ