We propose a framework in which physical reality is fundamentally a two-dimensional topological surface M², three-dimensional space emerges as a stable projection, and quantum correlations—including Bell-inequality violations—arise from topological hidden variables whose structure is explicitly specified. The hidden variable is the topological triple λ = (n, g, φT): winding number, genus, and topological phase. This yields a specific correction to quantum predictions: CTCH (a, b) = −cos θ + ε·f (n, g, θ), where f is a harmonic function numerically determined from Fibonacci anyon simulations and ε ~ 10⁻³⁵. The dimensional hierarchy 0D → 1D → 2D → 3Dₚrojected is derived from three premises—existence, finitude, and distinguishability—through a universal transition principle. Numerical evidence from companion papers demonstrates that topological sectors carry statistically significant mutual information with CHSH values, that Bell violation is generic in Fibonacci anyon braiding (64. 6%–91. 8% of sequences at L=9), and that a single topological generator controls entanglement as an exact on/off switch. We present eight falsifiable predictions, including autocorrelation in Bell-test detection order (ACF (1) ∈ 0. 24, 0. 50) and spectral fingerprints that distinguish topological orders. TCH specifies the hidden-variable structure explicitly, yielding falsifiable predictions through the harmonic pattern of f (n, g, θ). v1. 3: Separability/free-choice clarification with Vieira et al. 2025 comparison; ACF qualifier and range updated to 0. 24, 0. 59; SIM-01/02 numerical verification footnotes added.
Berkay Yüksel Sayim (Thu,) studied this question.