Temporal Dynamics: A Unified Baseline-Consistency Framework for Gravity, Electromagnetism, and Wave Transport

This paper presents a unified Temporal Dynamics (TD) formulation of gravity, electromagnetism, wave propagation, and annihilation using a single baseline-relay framework. In TD, the baseline relay speed is fixed at S ≡ c, while local physical departures from the reference state are encoded by a lag field ΔT(x,t) and a signed texture-load χ ≡ qΔT. Gravity is modeled as the baseline curvature response to gradients in ΔT, while electric interaction is derived as signed texture-resolution of the same textured carrier-curve. Magnetism emerges as a motion-induced transverse warp-leftover generated when direct texture stretching is forbidden by baseline consistency. Radiation is interpreted not as a separate substance but as transported field-state difference generated by source-state transitions. The paper extends the signed-ΔT structure to annihilation, treating radiative output as the collapse of static carrier-texture disagreement into propagating baseline difference-content. A prediction section identifies testable signatures, including timing–difference transport separation, electric boundary saturation behavior, and strong-curvature magnetic amplification. The framework is presented as an operational and falsifiable platform intended for mathematical refinement, numerical simulation, and empirical comparison.