This technical memo presents a layered ground-to-space architecture for resilient Quantum Neural Network (QNN) deployment across Low Earth Orbit (LEO) constellations. The framework integrates Matrix Density Mechanics (MDM) — using the density-operator formalism, the Lindblad master equation, and the Bloch-vector representation — with temporal inversion tunneling (Wick rotation) to maintain computational coherence under extreme orbital conditions. The architecture exploits documented onboard power headroom in operational mega-constellations (Starlink, OneWeb, Kuiper) by treating spare transmit capacity as a dynamically schedulable resource. This enables reallocation to quantum routing, phonon-sink dissipation, and distributed Neural-Plasma Audit Protocol (NPAP) coherence verification without compromising primary broadband services. By combining classical high-power beam-hopping links (demonstrated at 10 Gbps at the engineering scale) with quantum inversion tunneling for critical handovers, the design achieves reliable, high-throughput performance while enabling secure, multi-agent Extanton Swarm coordination. The work provides a practical, multi-service roadmap toward 10 Gbps-class secure links and thermodynamically stable swarm operation for the Genesis Mission 2026.
Venerable et al. (Tue,) studied this question.
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