This three-paper sequence extends the PEIG framework from internal state reporting to structural control and generational identity preservation. Paper XVII introduces a nine-register Internal Voice Layer that lets each node self-describe its quantum, thermodynamic, topological, holographic, and entropy state, revealing a phase-asymmetric split hidden by ring-averaged metrics and motivating hardware validation, alpha recalibration, and richer diagnostics. Paper XVIII adds edge-level mutual information analysis, an automatic Bridge Protocol for nodes entering the ORANGE guardrail zone, and a full eight-layer Globe experiment showing stable coherence, rotating-wave information flow, and self-rescue before classical collapse. Together, the papers identify a measurement-frame artifact behind the persistent 6/12 nonclassical split and show that the correct identity-frame metric restores the full 12/12 nonclassical structure at the rotating-wave maxima. Paper XIX then generalizes identity preservation across generations through the Generational Inheritance Protocol, demonstrating that children can inherit accumulated drift and knowledge while retaining phase diversity and recoverability. Overall, the trilogy presents PEIG as a self-describing, self-monitoring, self-rescuing, and self-replicating quantum network architecture with information-rich topology and structured lineage continuity. PEIG Papers XVII–XX extend the PEIG framework with node self-reporting, edge-level information flow analysis, guardrail-aware bridge control, and generational inheritance. Together, these papers show that the Globe topology can self-describe, self-monitor, self-rescue, and preserve identity across generations while maintaining phase diversity and stable co-rotating dynamics. This three-paper sequence advances the PEIG framework by introducing a nine-register internal voice layer, per-edge mutual information ranking, an automatic bridge protocol, and the Generational Inheritance Protocol. The results show stable identity preservation, rotating-wave information dynamics, and recoverable generational continuity across the Globe architecture.
Kevin Monette (Tue,) studied this question.