The Geometry of Intelligence: Deterministic Functional Topology as a Foundation for Real-World Perception

Real-world physical processes do not generate arbitrary variability: their signals concentrate on compact and low-variability subsets of functional space. This geometric structure enables rapid generalization from a few examples in both biological and artificial systems. This work develops a deterministic functional-topological framework in which the set of valid realizations of a physical phenomenon forms a compact perceptual manifold with stable invariants and a finite Hausdorff radius. We show that the boundaries of this manifold can be discovered in a fully self-supervised manner through Monte Carlo sampling, even when the governing equations of the system are unknown. We provide theoretical guarantees, practical estimators of knowledge boundaries, and empirical validations across three domains: electromechanical railway point machines, electrochemical battery discharge curves, and physiological ECG signals. Our results demonstrate that deterministic functional topology offers a unified mathematical foundation for perception, representation, and world-model construction, explaining why biological learners and self-supervised AI models can generalize from limited observations.