Translation and Rotation Equivariant Normalizing Flow (TRENF) for Optimal Cosmological Analysis

TL;DR

This paper introduces TRENF, a symmetry-aware normalizing flow model for cosmological data analysis that preserves full information and improves parameter constraints over traditional methods.

Contribution

The work develops TRENF, a novel equivariant normalizing flow that explicitly incorporates translation and rotation symmetries for cosmological likelihood estimation.

Findings

TRENF accurately models Gaussian random fields with analytical likelihood agreement.

TRENF improves parameter constraints over power spectrum analysis in nonlinear simulations.

TRENF's generative capabilities produce data samples consistent with N-body simulations.

Abstract

Our universe is homogeneous and isotropic, and its perturbations obey translation and rotation symmetry. In this work we develop Translation and Rotation Equivariant Normalizing Flow (TRENF), a generative Normalizing Flow (NF) model which explicitly incorporates these symmetries, defining the data likelihood via a sequence of Fourier space-based convolutions and pixel-wise nonlinear transforms. TRENF gives direct access to the high dimensional data likelihood p(x|y) as a function of the labels y, such as cosmological parameters. In contrast to traditional analyses based on summary statistics, the NF approach has no loss of information since it preserves the full dimensionality of the data. On Gaussian random fields, the TRENF likelihood agrees well with the analytical expression and saturates the Fisher information content in the labels y. On nonlinear cosmological overdensity fields from N-body simulations, TRENF leads to significant improvements in constraining power over the standard power spectrum summary statistic. TRENF is also a generative model of the data, and we show that TRENF samples agree well with the N-body simulations it trained on, and that the inverse mapping of the data agrees well with a Gaussian white noise both visually and on various summary statistics: when this is perfectly achieved the resulting p(x|y) likelihood analysis becomes optimal. Finally, we develop a generalization of this model that can handle effects that break the symmetry of the data, such as the survey mask, which enables likelihood analysis on data without periodic boundaries.