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Finite‑Response Gravity and the Scale‑Dependent Structure of Post‑Newtonian Dynamics

March 21, 2026

Finite-Response Coupled Field Dynamics (FRCFD) Phase 4: Running Substrate Capacity, Precision Constraints, and Controlled Cosmological Extension The visualization below illustrates the extreme optical response of spacetime near a compact object. In FRCFD, similar features emerge not from geometry but from the saturation of a finite‑capacity substrate. Author: Derek Flegg Date: March 21, 2026 Table of Contents 1. Theoretical Position and Upgrade 2. Running Capacity and Invariant Scale 3. Weak-Field Structure 4. Orbital Dynamics 5. Perihelion Precession 6. Mercury Constraint 7. EFT Functional Form 8. Two-Regime Structure 9. Cosmology (Constrained / Speculative) 10. Falsifiability 1. Theoretical Position and Upgrade FRCFD replaces geometric gravity with a finite-response scalar substrate S. Earlier formulations assumed a constant capacity S_max, which produces a direct inconsistency: Weak-field: S_max ≈ 1 Strong-field: S_max ≈ 0.3–0.5 Phase ...

From Fixed Capacity to Flow: The Renormalization of the Substrate in FRCFD

March 21, 2026

Phase 4: Running Substrate Capacity and Effective Field Theory Structure Abstract This work presents the Phase 4 evolution of Finite-Response Coupled Field Dynamics (FRCFD), transforming the framework from a fixed-parameter substrate model into a fully scale-dependent Effective Field Theory (EFT). By promoting the substrate's maximum response capacity S_max to a running invariant S_eff(sigma), the theory acquires a Renormalization Group (RG) structure with an infrared fixed point and ultraviolet saturation. The running scale sigma is defined through local Lorentz-invariant stress measures, ensuring that the substrate's response is governed solely by physical field intensity. A saturating functional form for S_eff(sigma) is introduced, eliminating Landau-pole-like divergences and enforcing finite behavior in strong-field regimes. This dynamical evolution induces a scale-dependent flow in the Parametrized Post-Newtonian (PPN) coefficients, providing a concrete observat...

RST + FRCFD — Chronological Index (Newest → Oldest)

March 21, 2026

RST + FRCFD — Chronological Index (Newest → Oldest) Coverage: Mar 21 → Feb 6 Table of Contents March 21 March 20 March 19 March 18 March 17 March 16 March 15 March 14 Feb 13 → Feb 6 March 21 Reciprocity Theorem from Null Geodesics in FRCFD PPN Structure and Substrate Back‑Reaction in FRCFD Nonlocal Frame Response and Field‑Theoretic PPN Extraction Back to top March 20 Finite‑Response Coupled Field Dynamics (FRCFD): Classical Tests, Field Derivation, and GR Correspondence Finite‑Response Coupled Field Dynamics (FRCFD): From Strong‑Field Astrophysics to Cosmological Redshift Nonlinear Frequency Decay: A Substrate‑Impedance Model of Cosmological Redshift Nonlinear Vacuum Impedance and the Covariant Suppression of Temporal Update‑Rates Summary of Dimensional Efficiency: 4 Forces, 1 Substrate X. The Core New Idea: A Self‑Regulating Feedback Loop The Principle of Physical Admissibility: Pruning the Infinite Back to to...

Reciprocity Theorem from Null Geodesics in FRCFD

March 21, 2026

Einstein showed that light stretches when space expands. But what if light stretches even when space doesn’t? The Null-Geodesic Derivation of the Reciprocity Theorem in FRCFD Derek Flegg Southern Ontario, March 21, 2026 1. Introduction: From Analogy to Derivation In standard FLRW cosmology, the relationship between luminosity distance (d_L) and angular diameter distance (d_A) — the Etherington Reciprocity Theorem — is a direct consequence of metric expansion. Any static-background alternative must reproduce the same scaling: d_L = d_A * (1 + z)^2 In Finite-Response Coupled Field Dynamics (FRCFD), this relation is not assumed. It emerges naturally from the substrate response function f(S) and the structure of the effective propagation metric. 2. The Cosmological Substrate Metric We model the cosmological background as a cumulative substrate stress field: S(chi) = gamma * chi The effective FRCFD metric is: ds^2 = f(S)^2 dt^2 - f(S)^(-2) dchi^2 -...

PPN Structure and Substrate Back‑Reaction in FRCFD

March 21, 2026

Substrate Self‑Glow and PPN Refinement in FRCFD Derek Flegg Southern Ontario, March 2026 Table of Contents 1. Self‑Sourced Substrate Field Equation 2. Transition to Saturation 3. Second‑Order Metric Expansion 4. Derivation of the PPN β Parameter 5. Physical Consistency and GR Limit 1. Self‑Sourced Substrate Field Equation Beyond the test‑particle limit, the substrate field S carries its own energy density and therefore contributes to its own sourcing. In a static, spherically symmetric vacuum outside a central mass, the field equation becomes: d²S/dr² + (2/r)dS/dr - beta*S³ = -g * rho_substrate where: rho_substrate = 1/2 (dS/dr)² + (beta/4) * S⁴ This nonlinear feedback means the substrate “feels” its own intensity. In the far field, the nonlinear terms decay faster than the Laplacian, preserving the Newtonian limit. Closer to the source, the substrate’s self‑energy adds a small but finite contribution to the effective mass profile—an effect...

Nonlocal Frame Response and Field-Theoretic PPN Extraction

March 21, 2026

Nonlocal Frame Response and Field-Theoretic PPN Extraction Derek Flegg Southern Ontario, March 2026 Table of Contents 1. Nonlocal Frame Response (omega(r)) 2. PPN Parameter Extraction (gamma, beta) 3. Full Geodesic Derivation 4. Energy Conditions and Stability 5. Numerical Solutions for the S Equation 1. Nonlocal Frame Response (omega(r)) In FRCFD, rotational effects are not treated as the geometric "dragging" of a manifold, but as a nonlocal coupling between the angular momentum density J_sub and the substrate field. The effective angular velocity omega(r) is mediated by a kernel that accounts for the finite coherence length (ell) of the substrate: omega(r) = (kappa/r^2) * integral[ J_sub(r') * exp(-|r-r'|/ell) * f(S(r)) * f(S(r')) dr' ] This integral representation ensures that frame-dragging is suppressed in high-impedance regions where f(S) -> 0, preventing the unphysical infinite rotational velocities associated with standard K...