Biological and cognitive systems continuously operate under conditions of uncertainty, energetic limitation, finite integration capacity, and environmental instability. Existing frameworks in cognitive science and neuroscience frequently describe isolated aspects of adaptive regulation, including predictive processing, attentional control, salience assignment, executive regulation, and cognitive flexibility. However, fewer models attempt to integrate these processes within a unified constraint-based organizational framework. The present paper proposes Alignment Bandwidth (AB) as a higher-order regulatory construct describing the range of representational variability that a system can flexibly integrate while maintaining coherent adaptive functioning under constraint pressure. Within this framework, cognition is conceptualized not as unrestricted information processing, but as the dynamic regulation of uncertainty through selective stabilization, compression, and representational organization. The framework is grounded in the Meaning Cost (MC) formulation: MC ∝ S + B + K + Twhere: • S represents scenario generation, • B contextual complexity, • K self-referential integration, • and T temporal projection. Increasing MC elevates integrative demands on the system, requiring adaptive modulation of alignment bandwidth. Optimal functioning is proposed to emerge within a bounded regulatory regime balancing exploratory flexibility and stabilization capacity. Excessive narrowing produces rigidity and over-stabilization, whereas excessive expansion produces fragmentation, instability, and dysregulated variability. To further characterize these dynamics, the framework introduces two interacting regulatory dimensions: • Perceptual Noise (PN), • and Belief Rigidity (BR). Together, these dimensions define a continuous regulatory landscape linking adaptive flexibility, defensive compression, fragmentation, recursive overload, and stabilization failure. The paper further examines: • recursive stress reactivation, • self-observation as a bandwidth regulator, • intrinsic motivation as exploratory stabilization, • and collective/social alignment processes within the same constraint-based architecture. Importantly, the framework does not propose a categorical clinical model or a reductionist neural theory. Rather, it offers a scalable conceptual structure intended to organize cognitive, behavioral, and social phenomena through shared principles of uncertainty regulation and bandwidth modulation. Finally, the paper outlines experimentally testable predictions concerning: • bandwidth narrowing, • overexpansion, • recursive uncertainty dynamics, • self-monitoring effects, • and instability under informational overload. The proposed framework suggests that adaptive cognition depends not on maximizing certainty or information processing alone, but on dynamically regulating representational breadth within bounded stability limits under constraint pressure.
Reyhan Karatas (Tue,) studied this question.