A Geometric Framework for Fundamental Parameters: Investigating the Dimensional Information Cascade (SFT v3600)

While the Standard Model (SM) provides an unparalleled description of particle dynamics, the origin of its fundamental parameters and mass hierarchies remains a central question in theoretical physics. This paper introduces the SFT v3600 framework, which explores a geometric derivation of these constants through a concept termed the Dimensional Information Cascade. Rather than treating physical constants as independent input parameters, this model investigates their potential emergence from layered topological constraints: Dimensional Transitions: We explore the hypothesis that information density shifts from a fractal UV-background (dₛ 1. 2) to localized 3D resonances. Planar Correlations: Utilizing Principal Component Analysis (PCA) on quark-related metrics, we identify a statistical preference for planar (2D) configurations, suggesting a geometric basis for the quark sector. Topological Coupling: By applying constants derived from vacuum symmetries—specifically the Oₕ (octahedral) symmetry and an instanton-based bridge to the Vacuum Expectation Value (VEV) —the model seeks to calculate the mass ratios of the lepton and boson sectors. The accompanying Python protocol (SFTᵥ3600. py) provides a transparent computational environment to reproduce these numerical correlations. Preliminary results show that the values derived from these geometric axioms align closely with CODATA experimental data, offering a heuristic perspective on the "why" behind the Standard Model's parameter space.