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| Hovedforfatter: | |
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| Format: | Recurso digital |
| Sprog: | engelsk |
| Udgivet: |
Zenodo
2026
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| Fag: | |
| Online adgang: | https://doi.org/10.5281/zenodo.20028683 |
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Indholdsfortegnelse:
- <p>We present Meridian, a four-layer deterministic wireless energy routing architecture that unifies ambient energy harvesting, burst-mode storage, mesh-based relay coordination, and directed wireless power delivery under a single governing framework. Meridian defines a universal energy coordinate system, a deterministic flow engine, a multi-hop mesh fabric, and a directional transmission layer —” designated Meridian Core (MC), Meridian Flow Engine (MFE), Meridian Mesh Fabric (MMF), and Meridian Transmission Layer (MTL) respectively. These four layers are vertically coupled and governed by a set of global invariants that guarantee deterministic, loss-bounded, and safe energy propagation across the network regardless of ambient variability. Meridian integrates three established DarkWave subsystems: DWER (Deterministic Wireless Energy Routing) for point-to-point directed beam delivery, DRMA (Distributed Relay Mesh Architecture) for multi-hop energy routing, and DAEH (Deterministic Ambient Energy Harvesting) for node-autonomous power accumulation. The architecture is controlled by Lume-X, a provisionally patented deterministic control runtime validated at 73 Hz cycle frequency, and enforced by Guardian Security (energy-domain designation: Guardian-E), the security layer hosted at TrustShield.tech, which addresses eleven threat categories including localization spoofing, routing table manipulation, beam hijacking, and denial-of-power attacks. The primary technical contributions of this work are: (1) the first formal definition of deterministic wireless energy routing as a network protocol stack, with power nodes addressed as IP devices, routing tables adapted from OSPF and BGP equivalents, and quality-of-service guarantees applied to watt delivery; (2) the Self-Healing Deterministic Control Layer (SHDCL), which provides continuous autonomous recovery from failure conditions across all three physical subsystems without human intervention; (3) a formal, testable determinism standard for wireless power delivery defined by four required measurements —” received power P_min (mW), spatial uncertainty radius r (cm), trial variance σ² (%), and distance d (m); (4) a burst-mode ambient harvesting integration model that makes node autonomy a first-class architectural layer rather than a supplementary subsystem; and (5) a formal biological safety layer with real-time RF exposure monitoring and automatic threshold enforcement. No experimental data currently exists for this architecture. This paper establishes the formal theoretical and architectural foundation. No deployment-scale capability claims are made. Phase 1 experimental validation is the immediate next step. Keywords: deterministic wireless energy routing, mesh energy networks, ambient energy harvesting, phased-array beamforming, self-healing control systems, deterministic control, wireless power transfer, network protocol stack for energy, burst-mode storage, biological safety layer, SHDCL, Lume-X</p> <p><em>Protected under U.S. Provisional Patent Application No. 64/032,339, Filed April 7, 2026.</em></p>