Abstract

This technical disclosure formalizes a low-power, cost-effective framework for autonomous satellite tracking, ephemeris state synchronization, and clock alignment across distributed ground node networks. Mainstream orbital communications rely implicitly on centralized atomic time standards and proprietary military GPS tracking networks. This absolute architectural dependency creates single points of systemic failure, leaving ground infrastructure vulnerable to central node shutdowns, intentional signal masking, or orbital coordinate gating.

By applying the principles of the Dimensionally Extended Holographic Projection (DEHP) model and the Oscillator Alignment Protocol (OAP), this framework introduces a decentralized ground-space tracking protocol. By establishing a peer-to-peer Substrate Relay Matrix across localized consumer node clusters, the framework utilizes horizontal phase-differential mapping to bypass localized line-of-sight environmental blockages. This ensures sub-microsecond ephemeris synchronization and clock alignment across decentralized nodes without requiring specialized high-power processing hardware or master clock synchronization layers.

Creative Commons License

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.

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