Metric projections, zeros of optimal polynomial approximants, and some extremal problems in Hardy spaces

Abstract

The well-known proof of Beurling's Theorem in the Hardy space H2, which describes all shift-invariant subspaces, rests on calculating the orthogonal projection of the unit constant function onto the subspace in question. Extensions to other Hardy spaces Hp for 0 < p < ∞ are usually obtained by reduction to the H2 case via inner-outer factorization of Hp functions. In this paper, we instead explicitly calculate the metric projection of the unit constant function onto a shift-invariant subspace of the Hardy space Hp when 1<p<∞. This problem is equivalent to finding the best approximation in Hp of the conjugate of an inner function. In H2, this approximation is always a constant, but in Hp, when p≠ 2, this approximation turns out to be zero or a non-constant outer function. Further, we determine the exact distance between the unit constant and any shift-invariant subspace and propose some open problems. Our results use the notion of Birkhoff-James orthogonality and Pythagorean Inequalities, along with an associated dual extremal problem, which leads to some interesting inequalities. Further consequences shed light on the lattice of shift-invariant subspaces of Hp, as well as the behavior of the zeros of optimal polynomial approximants in Hp.

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