This paper establishes that real-time, multi-layer remote telemetry and high-dimensional data routing are fundamental physical requirements for maintaining resilient cislunar infrastructure within Earth’s closed thermodynamic system. By applying the d-dimensional Landauer erasure limit to high-alphabet qudrit state encoding, analyzing structural and geological alignment constraints from TeV-scale accelerator design, and modeling passive phononic crystal attenuation for lunar surface sensors, the analysis demonstrates that classical centralized linear architectures are structurally inadequate for sustained cislunar operations. A decentralized hierarchical architecture based on concentric redundant halos and eight-vector multi-directional lattice routing is proposed. This framework attenuates entropic surges at the edge before they propagate, while providing intrinsic cryptographic distribution of state information. The work integrates directly with the 2022 White House National Cislunar Science & Technology Strategy objectives and demonstrates architectural synergy with the Lunar Accelerometer Network Gravitational Observatory (LANGO) proposal through passive seismic and thermal isolation. The framework provides a mathematically rigorous and thermodynamically grounded pathway for persistent, secure, and long-duration deep-space swarm operations aligned with the Genesis Mission objectives.
Venerable et al. (Wed,) studied this question.
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