The smoothest average: Dirichlet, Fej\'er and Chebyshev

Abstract

We are interested in the ``smoothest'' averaging that can be achieved by convolving functions f ∈ 2(Z) with an averaging function u. More precisely, suppose u:\-n, …, n\ R is a symmetric function normalized to Σk=-nnu(k) = 1. We show that every convolution operator is not-too-smooth, in the sense that f ∈ 2(Z) \| ∇ (f*u)\|2(Z)\|f\|2≥ 22n+1, and we show that equality holds if and only if u is constant on the interval \-n, …, n\. In the setting where smoothness is measured by the 2-norm of the discrete second derivative and we further restrict our attention to functions u with nonnegative Fourier transform, we establish the inequality f ∈ 2(Z) \| (f*u)\|2(Z)\|f\|2(Z) ≥ 4(n+1)2, with equality if and only if u is the triangle function u(k)=(n+1-|k|)/(n+1)2. We also discuss a continuous analogue and several open problems.