The Hermite-Hadamard inequality in higher dimensions

Abstract

The Hermite-Hadamard inequality states that the average value of a convex function on an interval is bounded from above by the average value of the function at the endpoints of the interval. We provide a generalization to higher dimensions: let ⊂ Rn be a convex domain and let f: → R be a convex function satisfying f |∂ ≥ 0, then 1|| ∫f ~d Hn ≤ 2 π-1/2 nn+1|∂ | ∫∂ f~d Hn-1. The constant 2 π-1/2 nn+1 is presumably far from optimal, however, it cannot be replaced by 1 in general. We prove slightly stronger estimates for the constant in two dimensions where we show that 9/8 ≤ c2 ≤ 8. We also show, for some universal constant c>0, if ⊂ R2 is simply connected with smooth boundary, f: → R is subharmonic, i.e. f ≥ 0, and f |∂ ≥ 0, then ∫f~ d H2 ≤ c · inradius() ∫∂ f ~dH1. We also prove that every domain ⊂ Rn whose boundary is 'flat' at a certain scale δ admits a Hermite-Hadamard inequality for all subharmonic functions with a constant depending only on the dimension, the measure || and the scale δ.