English

Passive approximation and optimization using B-splines

Numerical Analysis 2017-11-22 v1

Abstract

A passive approximation problem is formulated where the target function is an arbitrary complex valued continuous function defined on an approximation domain consisting of a finite union of closed and bounded intervals on the real axis. The norm used is a weighted Lp\text{L}^p-norm where 1p1\leq p\leq\infty. The approximating functions are Herglotz functions generated by a measure with H\"{o}lder continuous density in an arbitrary neighborhood of the approximation domain. Hence, the imaginary and the real parts of the approximating functions are H\"{o}lder continuous functions given by the density of the measure and its Hilbert transform, respectively. In practice, it is useful to employ finite B-spline expansions to represent the generating measure. The corresponding approximation problem can then be posed as a finite-dimensional convex optimization problem which is amenable for numerical solution. A constructive proof is given here showing that the convex cone of approximating functions generated by finite uniform B-spline expansions of fixed arbitrary order (linear, quadratic, cubic, etc) is dense in the convex cone of Herglotz functions which are locally H\"{o}lder continuous in a neighborhood of the approximation domain, as mentioned above. As an illustration, a typical physical application example is included regarding the passive approximation and optimization of a linear system having metamaterial characteristics.

Keywords

Cite

@article{arxiv.1711.07937,
  title  = {Passive approximation and optimization using B-splines},
  author = {Yevhen Ivanenko and Mats Gustafsson and B. L. G. Jonsson and Annemarie Luger and Börje Nilsson and Sven Nordebo and Joachim Toft},
  journal= {arXiv preprint arXiv:1711.07937},
  year   = {2017}
}
R2 v1 2026-06-22T22:53:04.534Z