Interferometric Sector–Gate Nervous Systems: Orchestrating AGI via Parity Fuse Quantum Primitives and Deterministic Java Injection - From Java Injection to Quantum Eigenstates: Engineering an n8n-Style Nervous System for AGI

We present a mathematically rigorous architecture that integrates measurement-first parity interferometry (“ParityFuse”) with a provable runtime orchestration layer (a capability-constrained Java injection agent) to form an n8n-like nervous system for an AGI substrate encoded in sectoral eigenstate dynamics.

We develop:
(i) the Hilbert-space sector factorization and operator calculus underpinning interferometric sector-gates,
(ii) the Tunneling-First optimization theorem for parity-limited readout devices and its asymptotic error-exponent consequences,
(iii) open-system stochastic master equations that govern measurement-induced cognitive transitions,
(iv) a formal measurement-only compilation mapping from logical sector gates to ParityFuse sequences (including RUS semantics and resource accounting), and
(v) a typed Java-injection operational semantics with formal verification obligations ensuring safe, auditable runtime compilation of AGI decisions into bounded-latency quantum control.

Empirical device statements and the ParityFuse primitive specification follow the interferometric device blueprints and topological-core optimality arguments in the accompanying technical materials. We will cover a jump operator that might prove to be an important missing link, and explain how an injection agent might be a stepping stone towards AGI.