Constraining the Hubble Constant with a Simulated Full Covariance Matrix Using Neural Networks
Abstract
The Hubble parameter, H(z), plays a crucial role in understanding the expansion history of the universe and constraining the Hubble constant, H0. The Cosmic Chronometers (CC) method provides an independent approach to measuring H(z), but existing studies either neglect off-diagonal elements in the covariance matrix or use an incomplete covariance matrix, limiting the accuracy of H0 constraints. To address this, we use a Positive-Definite Covariance Network (PD-CovNet) to simulate the full 33 × 33 covariance matrix based on a previously published 15 × 15 covariance matrix. Hyperparameters are chosen via leave-one-z-out validation, and performance is benchmarked against a Gaussian-process (GP) baseline. Under identical five-fold cross-validation over redshift groups, we prove that PD-CovNet is a reliable generator of the full covariance compared to the GP baseline. Using this full PD-CovNet-simulated covariance alongside three comparators with different covariance specifications, we constrain H0 with two independent methods (EMCEE and GP). Across all covariance specifications and both constraint methods, standardized differences and two-sided p-values show no statistically meaningful shift in the central value of the constrained H0. However, the precision of the constrained H0 depends on both covariance and method: EMCEE is uniformly more precise than GP once covariance is modeled; within a fixed method, incorporating more covariance reduces precision; and PD-CovNet hyperparameters have a modest effect on uncertainty. These results indicate the importance of accurate covariance modeling in CC-based H0 constraints.
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