Uniform Approximation by Polynomials with Integer Coefficients via the Bernstein Lattice
Abstract
Let CZ([0,1]) be the metric space of real-valued continuous functions on [0,1] with integer values at 0 and 1, equipped with the uniform (supremum) metric d∞. It is a classical theorem in approximation theory that the ring Z[X] of polynomials with integer coefficients, when considered as a set of functions on [0,1], is dense in CZ([0,1]). In this paper, we offer a strengthening of this result by identifying a substantially small subset n Bn of Z[X] which is still dense in CZ([0,1]). Here Bn, which we call the ``Bernstein lattice,'' is the lattice generated by the polynomials pn,k(x) := nk xk(1-x)n-k, ~~k=0,…,n. Quantitatively, we show that for any f ∈ CZ([0,1]), d∞(f, Bn) ≤ 94 ωf(n-1/3) + 2 n-1/3, ~~n ≥ 1, where ωf stands for the modulus of continuity of f. We also offer a more general bound which can be optimized to yield better decay of approximation error for specific classes of continuous functions.
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