SYSTEM ARCHITECTURE
WCF-1: Wireless Communications Fix One — System Layer Overview
(Public Mathematical Shell — IP-Restricted Core Redacted)
The WCF-1 architecture replaces continuous broadcast transmission with a mathematically regulated, ecologically compliant communication layer. All operational behaviour is determined by equilibrium law $ Eq(\mathcal{S}) $, PHM harm-weighting, NashMark allocation constraints, and Sentinel-governed Markov state transitions. The system is defined across four interacting strata: Ecological Sensing, Transmission Control, Harm Governance, and Equilibrium Enforcement.
2.1 Ecological Sensing Layer (Sentinel Public Shell)
The sensing layer provides biological and environmental feedback needed for conditional communication:
- Bioacoustic monitoring (insect wingbeat density, avian signatures)
- Thermal micro-imaging (small-body proximity mapping)
- Exposure field sampling (local SAR proxies and field drift vectors)
- Environmental state capture (light cycle, humidity, migration patterns)
It produces the real-time ecological state vector:
$ E_t = \{ \rho_{\text{insects}},\, \rho_{\text{birds}},\, \sigma_{\text{field}},\, \chi_{\text{drift}},\, \Lambda_{\text{exposure}} \} $
Any component exceeding its threshold triggers a Markov transition to a restricted or shutdown state.
2.2 Transmission Control Layer (Directional Beam Logic)
All communication transmission is non-static, directional, and state-dependent:
- Dynamic beam-forming (tight lobes, zero spill)
- Automated side-lobe suppression
- Duty-cycle modulation (transmit only under safe conditions)
- Proximity veto (beam collapse on biological intrusion)
- Exposure-bounded emission $ S \leq S_{\max} $
Transmission permission is defined by:
$ \tau_t = \Phi_{\text{sentinel}}(E_t) $
where $ \tau_t \in \{ \text{permit},\, \text{shape},\, \text{reduce},\, \text{deny} \} $. Unconditional broadcast is prohibited.
2.3 Harm Governance Layer (PHM Public Shell)
PHM assigns a proportional ecological cost to each transmission event:
$ \Delta\Omega_t = \alpha\,L_t + \gamma\,X_t + \zeta\,M_t $
where:
- $ L_t $ — transmission loss profile
- $ X_t $ — biological exposure density
- $ M_t $ — materials / operational footprint
A communication event is permitted only if:
$ \Delta c_t - \Delta\Omega_t \ge 0 $
2.4 NashMark Allocation Layer (Priority Enforcement)
Capacity is allocated by ethical priority, not throughput:
- Emergency signalling
- Medical and welfare channels
- Environmental telemetry
- Essential civic communication
- General data traffic
- High-load / discretionary bandwidth
The Nash objective ensures equilibrium fairness:
$ \max \sum_i w_i \log(U_i - U_i^0) $
2.5 Equilibrium Enforcement Layer (EEE / BCE Public Shell)
This layer enforces lawful operating states:
- EEE (Equilibrium Enforcement Engine): returns system to $ Eq(\mathcal{S}) $ under drift.
- BCE (Breach Cascade Engine): escalates violations into detunes and shutdowns.
Operational states include:
- Normal
- Constrained
- Reduced
- Critical
- Locked
All transitions are governed by Markov gateways.
2.6 System Structure Summary (Public Shell)
The WCF-1 system is expressed as:
$ \mathcal{W} = \langle E_t,\, \tau_t,\, \Delta\Omega_t,\, A_t,\, S_t \rangle $
- $ E_t $ — ecological state
- $ \tau_t $ — transmission permission
- $ \Delta\Omega_t $ — harm-weight
- $ A_t $ — Nash priority allocation
- $ S_t $ — Markov / Sentinel system state
All internal thresholds and operators remain sealed within the IP-restricted compliance API.
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