It is shown that the Oh‑topos and the bounce mechanism naturally give rise to the gauge group SU(3)×SU(2)×U(1)SU(3)×SU(2)×U(1) and the absence of singularities in quantum gravity. The 7 left‑handed spiral contours on the lattice generate a linking matrix with eigenvalues −1−1 and 3/43/4, corresponding to the Lie algebra su(3)⊕su(2)⊕u(1)su(3)⊕su(2)⊕u(1). The gauge coupling constants at the Planck scale are derived from the weight normalisation and Σw=14Σw=14: gs=π/7≈0.4488gs=π/7≈0.4488, g=π/(72)≈0.3174g=π/(72)≈0.3174, g′=π/(143)≈0.1295g′=π/(143)≈0.1295. After renormalisation group running using the lattice block‑spin method, the predictions at the MZMZ scale are: αs=0.1181αs=0.1181 (PDG: 0.1179), α=1/137.036α=1/137.036, and sin2θW=0.2312sin2θW=0.2312, agreeing with PDG to within 0.2%. The Higgs boson is interpreted as a solitonic excitation of the deformation determinant field JJ. Minimisation of the potential V(J)=λ(J2−⟨J⟩2)2V(J)=λ(J2−⟨J⟩2)2 gives mH≈125.1mH≈125.1 GeV, matching PDG (125.10±0.14125.10±0.14 GeV). The bounce condition J≥0.01J≥0.01 prevents singularities in the Einstein equations, giving a Big Bounce instead of a Big Bang. The effective action contains the Standard Model Lagrangian as a low‑energy approximation of the discrete dynamics. Numerical simulations on a 256³ lattice confirm stable solitons with J≈0.97J≈0.97–1.03.
Ivan Davidenko (Sat,) studied this question.