# Observing evolution from steady state

**Authors:** Herman Telkamp

arXiv: 1903.04894 · 2024-06-11

## TL;DR

This paper reinterprets cosmological observations within a stationary universe framework, deriving matter density and Hubble constant predictions that align with current empirical measurements.

## Contribution

It introduces a novel stationary universe model based on conformal transformations, predicting cosmological parameters consistent with observations.

## Key findings

- Predicts matter density Ω_m ≈ 1/24
- Derives Hubble constant h ≈ 0.72
- Aligns with Planck 2018 results

## Abstract

The time-translation symmetry of the conformal FLRW frame $\bar{g}=a^{-2}g$ allows reinterpretation of cosmological observation in the static space of a stationary universe, where constant matter density $\bar{\rho}_{\textrm{m}}=\rho_{\textrm{m0}}$ induces constant curvature $R_{0}^{-2}$. A hyperbolic de Sitter solution arises from equipartition of the kinetic energy of recessional and peculiar components of the gravitational field, corresponding to a total density $24R_{0}^{-2}$ of twice the scalar curvature. This predicts a matter density $\Omega_{\textrm{m}}=\frac{1}{24}$, or a Hubble constant $h=\sqrt{24\rho_{\textrm{m0}}}\approx0.72$, in agreement with distance-ladder estimates. Projecting the equilibrium state onto the $\Lambda\textrm{CDM}$ model returns $\hat{h}=\frac{4}{3}\sqrt{12\rho_{\textrm{m0}}}\approx0.68$ and exact densities $\hat{\Omega}_{\textrm{m}}=1-\hat{\Omega}_{\Lambda}=[\textrm{sinh}(\frac{4}{3}\textrm{asinh}(1))^{2}+1]^{-1}=0.3179...$, within confidence limits of Planck 2018 results.

## Full text

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## References

13 references — full list in the complete paper: https://tomesphere.com/paper/1903.04894/full.md

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Source: https://tomesphere.com/paper/1903.04894