Meridian: A Four-Layer Deterministic Wireless Energy Routing Architecture

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), 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; 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 Protected under U.S. Provisional Patent Application No. 64/032,339, Filed April 7, 2026.