The Unified Field Specification establishes the terminal mathematical closure of the cosmological vacuum using the Topological Geodesic Network Formalism (TGNF). This monograph shifts the fundamental physical ontology from continuous manifolds to a discrete, bipartite simplicial 1-complex, treating the universe as a matured informational hardware infrastructure. By deriving the vacuum’s Topological Impedance () and Maturation Constant (M) from first principles, this work provides a unified, scale-invariant resolution to eight primary observational anomalies that remain unresolved in standard Lambda-CDM and particle physics models. Key Mathematical & Observational Highlights: Geometric Unity: Establishes the Bipartite Handshake logic, unifying the microscopic Proton Mass resolution (938. 284 MeV) with the macroscopic Cosmic Dawn thermalization. Hubble Tension Closure: Resolves the discrepancy via Shannon Refresh Decay, aligning the local yield (73. 39 km/s/Mpc) with the global refresh rate (73. 82 km/s/Mpc). Dark Matter Resolution: Identifies galactic rotation anomalies as Radial Lattice Tension, predicting macroscopic quantized velocity steps of 1. 1877 m/s (testable via GAIA DR4). EDGES Anomaly: Predicts the 21-cm absorption dip at 509. 65 mK by modeling early-universe network transparency. Mass Hierarchy: Provides "honest math" (non-reverse-engineered) derivations for the Higgs Mass (124. 945 GeV) and the Neutrino Mass Floor (0. 05024 eV). This monograph serves as the terminal physical specification of the Interaction Line Protocol (ILP), offering a falsifiable, zero-defect roadmap for next-generation experimental verification.
Aayush Kumar Mayank (Tue,) studied this question.