English

The multidimensional truncated Moment Problem: Carath\'eodory Numbers

Functional Analysis 2018-04-20 v2

Abstract

Let A\mathcal{A} be a finite-dimensional subspace of C(X;R)C(\mathcal{X};\mathbb{R}), where X\mathcal{X} is a locally compact Hausdorff space, and A={f1,,fm}\mathsf{A}=\{f_1,\dots,f_m\} a basis of A\mathcal{A}. A sequence s=(sj)j=1ms=(s_j)_{j=1}^m is called a moment sequence if sj=fj(x)dμ(x)s_j=\int f_j(x) \, d\mu(x), j=1,,mj=1,\dots,m, for some positive Radon measure μ\mu on X\mathcal{X}. Each moment sequence ss has a finitely atomic representing measure μ\mu. The smallest possible number of atoms is called the Carath\'eodory number CA(s)\mathcal{C}_{\mathsf{A}}(s). The largest number CA(s)\mathcal{C}_{\mathsf{A}}(s) among all moment sequences ss is the Carath\'eodory number CA\mathcal{C}_{\mathsf{A}}. In this paper the Carath\'eodory numbers CA(s)\mathcal{C}_{\mathsf{A}}(s) and CA\mathcal{C}_{\mathsf{A}} are studied. In the case of differentiable functions methods from differential geometry are used. The main emphasis is on real polynomials. For a large class of spaces of polynomials in one variable the number CA\mathcal{C}_{\mathsf{A}} is determined. In the multivariate case we obtain some lower bounds and we use results on zeros of positive polynomials to derive upper bounds for the Carath\'eodory numbers.

Keywords

Cite

@article{arxiv.1703.01494,
  title  = {The multidimensional truncated Moment Problem: Carath\'eodory Numbers},
  author = {Philipp J. di Dio and Konrad Schmüdgen},
  journal= {arXiv preprint arXiv:1703.01494},
  year   = {2018}
}
R2 v1 2026-06-22T18:35:43.139Z