This work presents a precision experimental protocol for testing whether driven nonequilibrium electromagnetic systems can produce measurable mechanical responses consistent with a fully constrained energy budget. Building on a thermodynamic framework developed for Emergent Vacuum Response Theory (EVRT), the protocol defines a complete measurement architecture for quantifying input power, stored electromagnetic energy, mechanical output, environmental coupling, and loss channels in high-voltage asymmetric systems. A torsion-balance-based apparatus is specified together with instrumentation requirements, calibration procedures, time-averaged data acquisition, and uncertainty propagation methods. The protocol incorporates null-test validation, artifact discrimination strategies, and scaling diagnostics, with explicit consideration of signal-to-noise limitations in the nanonewton regime. The central diagnostic quantity is a residual power term evaluated within an uncertainty-bounded framework. The objective is not to demonstrate violations of conservation laws, but to determine whether any reproducible signal remains after all identifiable contributions are accounted for. This provides a falsifiable and measurement-driven pathway for evaluating EVRT-class hypotheses under controlled experimental conditions.
Erick Sangalang (Sat,) studied this question.