Modern acoustic levitation has built an impressive experimental program — phased arrays, acoustic holograms, multi-frequency traps — without a unified mathematical foundation that explains why certain configurations work and others fail. This paper identifies structural correspondences between the mathematical structures researchers discovered empirically and the Intent Tensor Theory (ITT) Necessity Chain. We show that the Gor'kov potential is structurally analogous to the isotropic Allen-Cahn limit of the ITT Master Equation; the breakdown parameter corresponds to the upper bound Omega of the ITT selector S; the Willis coupling tensor shares the mathematical structure of the anisotropic collapse metric tensor Mᵢj; and the phased array trap condition corresponds to Closure Condition A from the ITT Triple Closure Theorem. The paper resolves a dimensional classification gap in the literature: acoustic holograms (Class III) and Chladni plates (Class IV — 3D compressed) are mathematically distinct classes. Computational proofs include 800-particle 3D simulations and FFT-based class distinction tests. The ICHTB transducer array geometry is derived from mathematical necessity. Source: https: //gitlab. com/intent-tensor-theory. com-group/ORCID: https: //orcid. org/0009-0004-8153-8335
Armstrong Knight (Wed,) studied this question.