We develop a rigorous geometric framework for inverse quantum design problems centered on the forward map Φ: Θ → ℝ, where Θ ⊂ ℝᵈ is a compact parameter space. The central result is a Stratified Robustness Control Law: under Gaussian fabrication disorder of amplitude ε, the variance of the observable satisfies ℛ (θ) = ε²‖∇Φ (θ) ‖² + O (ε⁴‖H_Φ‖²), with the leading coefficient identified as the Fisher-information pullback metric and the remainder bounded uniformly on each Whitney stratum. We prove that the loss landscape Hessian on the behavioral fiber factors algebraically as 2 DΦᵀ DΦ, yielding exactly d − rank (DΦ) flat fiber-tangential directions. Applied to the N = 4 quantum transport problem, Monte Carlo validation (200, 000 samples per noise level) recovers the predicted leading coefficient to 3. 4% accuracy and confirms the ε⁴ residual scaling. The framework is positioned as the second-order Taylor refinement of the first-order Symmetry-Forced Fiber Stability Theorem.
Francis Procaccia (Tue,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: