This paper executes the final translation of the Gradient Mechanics framework, moving from the Equation of State established in the ontological treatises to an Equation of Kinetics required for temporal analysis. We demonstrate that the static definition of reality as a Multiplicative Ratio (Gstate = E×C / F ) must undergo a dimensional transformation when observed through the lens of time (t). By differentiating the ontological equation with respect to time, we derive Kinetic Gradient Mechanics not as a separate hypothesis, but as the mathematical first derivative of Ontological Gradient Mechanics. We prove that the geometric “Volume of Possibility” (E ×C) transforms into the thermodynamic “Net Force” (∆ − Θ), and the regulatory “Registration” (F ) transforms into “Inverse Registration Density” (η). This derivation resolves the dimensional incoherence of the static state by providing a scalar-invariant kinetic equation: Output = (∆−Θ)×η. This equation governs the evolution of all non-equilibrium systems, from geochemical batteries to recursive computational architectures. The derivation demonstrates that kinetic mechanics is not an applied external model but the necessary time-derivative of the ontological primitives, establishing formal continuity between configuration and process.