Local Equivalence of Riemannian Submersions via Differential Invariants

Abstract

We study the local equivalence problem for Riemannian submersions under fiber-preserving isometries using differential invariants. After briefly recalling the vertical--horizontal splitting, the O'Neill tensors A and T, and the mean curvature H of the fibers, we outline a practical invariant-based equivalence workflow. Our main contribution is the analysis of a concrete model class: orbit submersions induced by a nowhere-vanishing Killing field K. In this class we derive explicit formulas for A and H in terms of the Killing data, namely the length function =|K| and the curvature 2-form =dθ| H of the associated connection 1-form θ, and we prove an equivalence criterion phrased purely in terms of the base data ( g,,). We further present a finite-order invariant decision procedure under a stated genericity assumption (with a practical stopping rule), together with a compact low-order invariant profile and computational remarks. Benchmark examples (product submersions, warped products, and the Hopf fibration) illustrate both the strengths and limitations of low-order scalar signatures.

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