Topological Determination of W and Z Boson Masses, the Weinberg Angle, and Charged-Lepton Mass Ratios

We present an information-theoretic account of electroweak and charged-lepton mass scales in which the relevant observables are first predicted as dimensionless ratios on a CPⁿ cascade. A single empirical GeV anchor (the Higgs vacuum expectation value v = 246. 22 GeV) then maps these ratios onto physical masses; no electroweak fit constants (GF, alpha (MZ), sin² thetaW) are used as inputs. The framework predicts: mW⁰ / v = 31 / (alpha^-1 ln 2) = 0. 32636 (PDG 0. 32636, +0. 002%) ; mZ / v = lambda₂ (T) / Tr (T) = 0. 37066 (PDG 0. 37035, +0. 08%) ; sin² thetaW = 0. 2247 (PDG 0. 22337, +0. 6%) ; mₘu/mₑ = 206. 748 (PDG 206. 7683, -0. 010%) ; mₜau/mₑ = 3476. 796 (PDG 3477. 23, -0. 013%). The capacitive integer core alpha^-1core = |11+4i|² = 137 and the dipole trace 109 + 137 = 246 are Born projections of the Higgs dipole; the procedural decimals delta = 0. 036 arise from a cosine-square fixed point at the CP⁴ exchanger. The same dressed phase delta governs the Z-mass eigenvalue of the asymmetric semantic tensor, the leading-order Weinberg angle, and the muon and tau mass corrections. A readout-induced uplift mW¹ = mW⁰ (1 + 4 alpha / 31) = 80. 433 GeV coincides with the CDF II result (80. 4335 +- 0. 0094 GeV) to 0. 07 sigma, while the current ATLAS, CMS, and LHCb measurements remain much closer to the floor mW⁰. The paper's main claim is therefore a joint topological determination of W floor, W readout uplift, Z eigenvalue, sin² thetaW, and charged-lepton ratios from a single dipole trace and a single dressed phase. Not peer reviewed. Prepared with the assistance of artificial intelligence.