Kaydedildi:
| Yazar: | |
|---|---|
| Materyal Türü: | Recurso digital |
| Dil: | |
| Baskı/Yayın Bilgisi: |
Zenodo
2026
|
| Konular: | |
| Online Erişim: | https://doi.org/10.5281/zenodo.18533493 |
| Etiketler: |
Etiketle
Etiket eklenmemiş, İlk siz ekleyin!
|
İçindekiler:
- <p>This paper develops the statistical modeling layer of Holosphere Theory by showing how deterministic angular coherence structure gives rise to ensemble-level measurement statistics. Individual measurement trials follow a fixed geometric projection rule, while observable variability arises from controlled structural differences across repeated preparations rather than intrinsic randomness.</p> <p>The paper introduces probability distributions over effective projection signals, formalizes threshold-based dropout as a structural measurement effect, and derives practical functional forms for dropout rates, correlation decay, and variance inflation under decreasing coherence. Synthetic ensemble simulations are used to illustrate three diagnostic signatures: projection histograms across coherence regimes, dropout probability as a function of detection threshold, and correlation profiles exhibiting a cutoff near a coherence angle threshold.</p> <p>These diagnostics provide a concrete inference framework for estimating structural parameters such as coherence visibility, detection threshold, coherence angle cutoff, ensemble variance, and coherence rank directly from observable statistics. The results establish a reproducible interface between deterministic coherence models and experimental observables, clarifying how quantum-like statistics can emerge from structured variability without postulating intrinsic probabilistic collapse.</p>