Manifold-Aware Information Gain and Lower Bounds for Gaussian-Process Bandits on Riemannian Quotient Spaces

Abstract

We prove a regret lower bound for Gaussian-process bandits on a smooth compact Riemannian manifold of dimension d with intrinsic Matérn-ν kernel (ν>d/2) that exposes how the geometry of the arm space enters the constant. For any algorithm and time horizon T exceeding an explicit threshold, the worst-case expected regret over the RKHS-ball \|f\|_kν\!\!B satisfies multline* [RT(f)]\;\;c*(d,ν)\,Bd/(2ν+d)\,σn2ν/(2ν+d) \\ ·\,g()ν/(2ν+d)\,T(ν+d)/(2ν+d)( T)ν/(2ν+d). multline* The exponent matches the Vakili--Khezeli--Picheny upper bound vakili2021information; the g()ν/(2ν+d) factor is, to our knowledge, the first explicit volume-dependent geometric constant in a manifold GP-bandit lower bound. We extend the analysis in five directions: (i)~a companion Assouad-style proof gives a different lower bound with a strictly smaller T-exponent (2ν+3d)/(4(ν+d)) but with a polylog factor of the form 1/( T)(2ν+d)/(4(ν+d)), sharpening the ( T)ν/(2ν+d) Fano polylog of Theorem~thm:main; (ii)~we prove a |G|1/2 upper bound on the regret of an extrinsic-kernel GP-UCB algorithm on a quotient space =/G, plus a bracketing theorem (Theorem~thm:gauge-bracket); the precise constant is conjectured to take the modulated form (1+(|G|-1)h(/κ))1/2 (Conjecture~conj:gauge-modulated), validated numerically on (3); (iii)~we write the leading constant c*(d,ν) out fully; (iv)~we extract a curvature dependence 1+O(KT2) via Bishop--Gromov; (v)~we transfer the bound to the Bayesian regret framework via the Yang--Barron / Castillo et al.\ Bayesian-Fano transfer.