A Complete Derivation of the Fermion Spectrum from the Recognition Composition Law

Abstract

We present a first-principles derivation of the masses of all twelve known fermions -- three charged leptons, six quarks, and three neutrinos -- and the fine-structure constant α-1, from a single discrete functional equation, the Recognition Composition Law (RCL), with zero continuously adjustable parameters. The mass spectrum follows from the RCL supplemented by four regularity conditions and eight structural theorems (T1--T8): the golden ratio =(1+5)/2 emerges as the unique hierarchy base (T6); an 8-step period is fixed by the 3-cube Hamiltonian cycle (T7); three spatial dimensions are selected by a unique combinatorial identity (T8). All integers entering the mass formula are the six combinatorial invariants of the 3-cube Q3; none is fitted. The sole empirical input is the electron mass, which fixes an irreducible unit-conversion constant~τ0. Predictions are confronted with PDG measurements. Charged-lepton masses are reproduced at sub-ppm accuracy for the muon and \!10-4 for the tau (Table~tab:leptonvalidation). All six quark masses are predicted at integer level; first-generation quarks agree to better than 1\%, while second/third-generation residuals of 2--16\% are expected integer-precision effects (Table~tab:quarkvalidation). Neutrino mass-squared splittings agree with NuFIT~5.3 within 1--2σ, normal ordering is predicted, and m≈ 0.063~eV satisfies cosmological bounds. All structural claims are machine-verified in Lean~4 (179 files, 0~sorry; github.com/ jonwashburn/ recognition-science).