This work develops a composite nonlinear stability operator for adaptive AI systems, formally grounded in operator theory and functional analysis. The framework models coupled dynamics across three interacting layers: Energetic transformation under bounded dissipation Reserve propagation with exponential chaining constraints Activation-layer dynamics governed by resonance-based logistic gating The operator is explicitly formulated in a Banach space and analyzed using: Lyapunov stability construction Jacobian spectral radius bounds Lipschitz continuity and contraction criteria Banach fixed-point theorem Explicit regime classification (dissipative, neutral, expansive, high-gain) The analysis establishes local stability conditions and derives conditional global convergence in dissipative regimes. Operator norm bounds and spectral constraints provide explicit criteria under which iterative application converges geometrically. A central result is the formal separation between energetic boundedness and activation-layer stability. The framework demonstrates that computational or energetic stability does not guarantee coherence at the activation or decision layer. This stability gap introduces a structural distinction relevant for systems exhibiting recursive activation, internal state modulation, and perturbation-driven adaptation. For advanced AI architectures, this distinction has implications for: Stability beyond surface performance metrics Robustness of adaptive and self-modifying agents Activation gating in recursive or deliberative systems Structural analysis of agent-level dynamics under perturbation No ontological claims are made regarding consciousness or agency. The contribution is strictly structural: a mathematically explicit operator architecture for analyzing stability and activation dynamics in complex adaptive systems. The framework is intended as a theoretical foundation for rigorous stability analysis in next-generation AI systems, particularly where recursive internal dynamics and activation thresholds interact with bounded resource propagation.
Neda Nadj (Wed,) studied this question.