Adaptive Nonparametric Estimation via Kernel Transport on Group Orbits: Oracle Inequalities and Minimax Rates
Abstract
We develop a unified framework for nonparametric functional estimation based on kernel transport along orbits of discrete group actions, which we term Twin Spaces. Given a base kernel K and a group G = acting isometrically on the input space E, we construct a hierarchy of transported kernels \Kj\j≥ 0 and a penalized model selection scheme satisfying a Kraft inequality. Our main contributions are threefold: (i) we establish non-asymptotic oracle inequalities for the penalized twin-kernel estimator with explicit constants; (ii) we introduce novel twin-regularity classes that capture smoothness along group orbits and prove that our estimator adapts to these classes; (iii) we show that the framework recovers classical minimax-optimal rates in the Euclidean setting while enabling improved rates when the target function exhibits orbital structure. The effective dimension deff governing the rates is characterized in terms of the quotient G/L, where L is the subgroup preserving the base operation. Connections to wavelet methods, geometric quantization, and adaptive computation are discussed.
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