Cartan meets Cram\'er-Rao
Abstract
A Cartan-geometric, jet bundle formulation of curvature-aware variance bounds in parametric statistical estimation is developed. Building on our earlier extrinsic Hilbert space approach to the Cram\'er-Rao and Bhattacharyya-type inequalities, we show that the curvature corrections induced by the square root embedding of a statistical model admit a canonical intrinsic interpretation via jet geometry and Cartan's prolongation theory. For a scalar-parameter family with square root map sθ=f(·;θ)∈ L2(μ), we regard sθ as a section of the statistical bundle E=× L2(μ) and study its finite-order prolongations. We point out that the classical algebraic efficiency condition--that the estimator residual (T-θ)sθ lies in the span of derivatives of sθ up to order m--is equivalent to the existence of a linear ordinary differential equation (ODE) of order m satisfied by the square root map. Geometrically, this means the prolonged section lies in an ODE-defined submanifold of the jet bundle and is an integral curve of the restricted Cartan vector field. The obstruction to such finite-order integrability is identified with the vertical component of the canonical Ehresmann connection on the jet tower, which coincides with the curvature correction term in variance bounds. This establishes a direct correspondence between algebraic projection conditions in L2(μ) and intrinsic holonomy properties of statistical sections, yielding a unified geometric interpretation of higher-order information inequalities.
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