Warped compactifications with multiple warped submanifolds generically admit an anisotropy between external and internal warp factors, which is often treated as a free continuous parameter. We show that this anisotropy is not arbitrary. The argument proceeds through three successive constraints: (i) the bulk Einstein equations on a Ricci-flat internal space establish a continuous family of anisotropic solutions; (ii) Israel junction conditions reduce this family to a single dimensionless ratio of boundary energy densities; and (iii) boundary topological consistency discretizes this ratio. The discretization is traced to the group cohomology H4(B(Z2 × Z9), Z) ≅ Z2 ⊕ Z9, whose torsion exponent lcm(2, 9) = 18 controls the fractional instanton lattice on transverse linking four-cycles. The boundary allocation selected under a minimal fractional unit principle yields the ratio ρ/σ = 1/17 and hence α = 3/2. The result removes an otherwise tunable degree of freedom and significantly increases the predictive content of warped compactifications without introducing additional stabilizing fields.
Mu Sung Lee (Sun,) studied this question.