Finite element approximation of the Hardy constant

Abstract

We consider finite element approximations to the optimal constant for the Hardy inequality with exponent p=2 in bounded domains of dimension n=1 or n ≥ 3. For finite element spaces of piecewise linear and continuous functions on a mesh of size h, we prove that the approximate Hardy constant converges to the optimal Hardy constant at a rate proportional to 1/| h |2. This result holds in dimension n=1, in any dimension n ≥ 3 if the domain is the unit ball and the finite element discretization exploits the rotational symmetry of the problem, and in dimension n=3 for general finite element discretizations of the unit ball. In the first two cases, our estimates show excellent quantitative agreement with values of the discrete Hardy constant obtained computationally.