Dist Babble

 What string theory is “missing” or misframing. Looking at my simulation and the lessons from it: Emergent Stability vs. Fine-Tuning In my network simulation, the effective dimensionality of coherent dynamics (δ_eff, phase ranges, holonomy defects) stabilizes naturally with feedback from local loops. Implication: In TFP, 4D spacetime and low-energy field content could emerge as a robust attractor , rather than needing strict fine-tuning like in traditional string theory (e.g., c = 26 for bosonic strings, fixed compactifications). String theory relies on exact algebraic consistency, whereas my framework shows how coherence feedback and topology naturally stabilize dynamics. Central Charges → Holonomy Feedback Virasoro constraints in string theory enforce central charges, anomalies, and conformal invariance. In TFP, these are replaced by loop defect sums and δ_eff dynamics . The “central extension” isn’t a fixed number—it’s emergent from the topology of loops and re...

  Temporal Flow Physics Cosmology: Predictions and Observational Tests 1. Emergent Patch-Dependent Expansion TFP reframes cosmological expansion as a statistical, patch-dependent phenomenon rather than a universal law: Local vs. Global Hubble Measurements : The persistent Hubble tension arises naturally: Local Cepheid measurements sample nearby coherence patches. CMB-derived H₀ averages over early-universe patch distributions. There is no single universal H₀; only statistical distributions emerge from patch-level dynamics. Line-of-Sight Correlations : Directional variations in distance moduli and apparent acceleration parameters are predicted. These should map onto underlying black hole populations and coherence patterns , producing correlated anisotropies across the sky. Anisotropy Signatures : Observers should detect preferred directions in expansion rates, subtle violations of isotropy, and holonomy residuals in high-precision gravitational wave timing...