The practical application of quantum entanglement for telemetry is currently constrained by the no-communication theorem, which treats non-local correlation as an inherently probabilistic state upon measurement. This paper proposes a deterministic optomechanical framework that bypasses probabilistic collapse by treating the entangled state as a rigidly coupled macroscopic oscillator system. By defining a mechanical decoherence threshold, we outline a sub-measurement methodology for phase manipulation. We propose a scalable, integrated optomechanical architecture utilizing silicon photonic ring resonators, phononic crystal isolation bandgaps, and piezoelectric nano-actuators. This schematic provides a theoretical and physical blueprint for applying sub-threshold geometric torque to non-local states, enabling deterministic phase modulation and theoretically permitting zero-latency data transmission.