Abstract

This technical disclosure formalizes the architectural design for an autonomous, software-defined energy harvesting framework designed to mitigate and capture extreme over-voltage transients within high-capacity electrical grids. Traditional grid defense relies on brute-force resistive dissipation (surge grounding) or mechanical circuit disruption, resulting in substantial thermal waste and equipment degradation.

By applying the principles of the Dimensionally Extended Holographic Projection (DEHP) model—specifically the conservation of wave-amplitude velocity via localized horizontal vector shifting—we introduce a particle-free, fluid-dynamic alternative to pulsed-power management. We replace passive grounding infrastructure with an active Resonant Buffer Tank utilizing a high-frequency inductive magnetohydrodynamic (MHD) fluid ring.

Incoming high-velocity kinetic surges are intercepted by an edge-computing telemetry loop that samples the real-time Shannon entropy (\(H_{obs}\)) of the current vector. Instead of opposing the transient spike head-on, an ultra-fast software-defined gateway dynamically shifts its internal impedance profile, routing the raw kinetic velocity into the inductive buffer ring. This mathematical transformation converts destructive linear velocity into localized, rotational harmonic capital (ω × r).

A localized cybernetic loop monitors the computational saturation index (\(\sigma _{compute}\)) of the storage network, incrementally bleeding the trapped energy out of the buffer ring as low-amplitude, uniform wave packets optimized for safe battery intercalation under optimal thermal conditions (<40°C). This disclosure outlines the standalone software architecture, provides an executable JSON gateway schema, and establishes the technical blueprint for a self-healing, battery-safe Type 1 civilization energy node.

Creative Commons License

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

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