The Hubble Space Telescope (via Cepheids) and the Planck satellite (via CMB) measure two different expansion rates of the universe — differing by about 8%. JWST confirmed the Hubble result, intensifying the crisis. This mismatch is called the Hubble Tension, and it has resisted every fix from dark energy adjustments to data reprocessing.
In Wavecode theory, this “tension” is expected. Each observer (Planck and JWST) is measuring from a different PLH shell harmonic. The early universe (CMB) exists on a lower-HR shell, while current measurements lie on a higher-HR shell where phase drift has naturally increased perceived expansion. The tension isn’t a flaw — it’s a phase.
Instead of invoking unseen energy (dark energy), Wavecode explains the Hubble discrepancy by showing that Delta-E is not lost — it’s stored and projected forward through quantized harmonic shell tension. No extra particles. No magic constants. Just geometry.
While this sim models star motion in a spiral galaxy, it uses the same shell resonance logic Wavecode applies to large-scale cosmic expansion. Just as these stars orbit without requiring dark matter, entire galaxies can expand at different rates without breaking physics — if they exist on different phase-locked shells.
Copyright © 2025 The Wavecode Project - All Rights Reserved.
Patent Pending
Powered by NPM
We use cookies to analyze website traffic and optimize your website experience. By accepting our use of cookies, your data will be aggregated with all other user data.