The technical disclosure titled "Rotational Substrate Field Theory: The Metric Translation Layer – Derivation of Field Equations and Natural Emergence of the Schwarzschild Metric" provides a formal mathematical bridge between the conceptual Nodal Truss substrate and the empirical observations of General Relativity. It moves the theory from a descriptive framework into a rigorous, first-principles derivation by utilizing the tools of classical field theory. In the section regarding the derivation via the Action Principle, the disclosure establishes a scalar Lagrangian density that defines the energy state of the rotational substrate. It then applies the Principle of Least Action and the Euler-Lagrange equations to force the emergence of dynamical field equations. A major highlight of the document is the natural emergence of the Schwarzschild metric from these derived field equations. The disclosure demonstrates that the reciprocal relationship between radial and temporal tension is a mathematical necessity of the field's stability and the invariance of the speed of light, rather than a rule imposed by hand. The paper further identifies gravity as a state of static substrate compression and velocity as a state of dynamic substrate shear. Both phenomena are unified within a single metric interval, ensuring that all motion follows the path of least rotational resistance, known as the geodesic. Finally, the disclosure provides a formal mathematical proof of the Weak Equivalence Principle. It shows that the universal coupling constant affects only the background metric, meaning the resulting equations of motion contain no dependence on a test body's mass or composition. Overall, the document serves as a publication-ready supplement intended to demonstrate that Rotational Substrate Field Theory is a self-consistent alternative to the standard curved empty space interpretation of gravity.
Anthony Bell (Tue,) studied this question.