Non-existence of Information-Geometric Fermat Structures: Violation of Dual Lattice Consistency in Statistical Manifolds with $L^n$ Structure

This paper reformulates Fermat’s Last Theorem as an embedding problem of information-geometric structures. We reinterpret the Fermat equation as an $n$-th moment constraint, constructing a statistical manifold $\mathcal{M}_n$ of generalized normal distributions via the Maximum Entropy Principle. By Chentsov’s Theorem, the natural metric is the Fisher information metric ($L^2$); however, the global structure is governed by the $L^n$ moment constraint. This reveals a discrepancy between the local quadratic metric and the global $L^n$ structure. We axiomatically define an “Information-Geometric Fermat Solution,” postulating that the lattice structure must maintain “dual lattice consistency” under the Legendre transform. We prove the non-existence of such structures for $n \ge 3$. Through the Poisson Summation Formula and Hausdorff-Young Inequality, we demonstrate that the Fourier transform induces an alteration of the function family ($L^n \to L^q$, where $1/n + 1/q = 1$), rendering dual lattice consistency analytically impossible. This identifies a geometric obstruction where integer and energy structures are incompatible within a dually flat space. We conclude by discussing the correspondence between this model and elliptic curves.

💡 Research Summary

The paper proposes a novel information‑geometric reformulation of Fermat’s Last Theorem (FLT). Instead of treating the Diophantine equation (x^{n}+y^{n}=z^{n}) as a purely number‑theoretic object, the authors interpret it as an (n)‑th absolute moment constraint on a random variable, i.e. (\mathbb{E}