Orbital Edge Computing via Supra-Laminar Quantum Entanglement: Decentralized Vacuum-Cooled Architectures for Deep Space Processing

Abstract As space missions extend toward the outer solar system, classical communication latencies and signal attenuation become critical failure points for real-time operations. This paper proposes a decentralized Orbital Edge Computing (OEC) framework utilizing supra-laminar quantum entanglement governed by the ARK5Q-200K protocol. By leveraging vacuum-cooled superconducting architectures inherent to the space environment, we demonstrate a zero-latency data synchronization method that bypasses traditional electromagnetic propagation limits. Our model utilizes 200, 000 logical qubits to maintain EPR-pair stability across inter-orbital nodes with a sub-femto resolution (10^-17 m). Numerical simulations indicate a processing capacity of 19. 1 quadrillion operations per second per node, providing the necessary infrastructure for autonomous deep-space navigation, large-scale data processing, and sovereign galactic connectivity. This architecture offers a robust backbone for the next era of human expansion, inviting a shift from terrestrial-dependent networks to a fully decentralized orbital cloud.