The sharp one-dimensional convex sub-Gaussian comparison constant

Abstract

Let X be an integrable real random variable with mean zero and two-sided sub-Gaussian tail P(|X|>t) 2e-t2/2 for all t 0. We determine the smallest constant c such that X is dominated in convex order by c G, where G is standard normal. Equivalently, c2 is the sharp one-dimensional convex sub-Gaussian comparison constant appearing in the Optimization Constants in Mathematics repository~optimization-constants-repo. We show that c is given by an explicit system of one-dimensional equations and is attained by an extremal distribution that saturates the tail constraint. Numerically, c ≈ 2.30952 (so c2 ≈ 5.33386). We also determine the analogous sharp constant under a two-sided sub-exponential tail bound, with convex domination by a scaled Laplace law. Finally, we record two higher-dimensional consequences: a sequential tensorization principle for multivariate convex domination, and a dimension-free Gaussian comparator for the cone generated by convex ridge functions (the linear convex order).