English

The average distance problem with an Euler elastica penalization

Analysis of PDEs 2022-01-26 v1

Abstract

We consider the minimization of an average distance functional defined on a two-dimensional domain Ω\Omega with an Euler elastica penalization associated with \pdΩ\pd \Omega, the boundary of Ω\Omega. The average distance is given by \begin{equation*} \int_{\Omega} \dist^p(x,\pd \Omega )\d x \end{equation*} where p1p\geq 1 is a given parameter, and \dist(x,\pdΩ)\dist(x,\pd \Omega) is the Hausdorff distance between {x}\{x\} and \pdΩ\pd \Omega. The penalty term is a multiple of the Euler elastica (i.e., the Helfrich bending energy or the Willmore energy) of the boundary curve \pdΩ{\pd \Omega}, which is proportional to the integrated squared curvature defined on \pdΩ\pd \Omega, as given by \begin{equation*} \la \int_{\pd \Omega} \kappa_{\pd \Omega}^2\d\H_{\llcorner \pd \Omega}^1, \end{equation*} where κ\pdΩ\kappa_{\pd \Omega} denotes the (signed) curvature of \pdΩ\pd \Omega and \la>0\la>0 denotes a penalty constant. The domain Ω\Omega is allowed to vary among compact, convex sets of R2\mathbb{R}^2 with Hausdorff dimension equal to 22\tcr{.} Under no a priori assumptions on the regularity of the boundary \pdΩ\pd \Omega, we prove the existence of minimizers of Ep,\laE_{p,\la}. Moreover, we establish the C1,1C^{1,1}-regularity of its minimizers. An original construction of a suitable family of competitors plays a decisive role in proving the regularity.

Keywords

Cite

@article{arxiv.2201.10097,
  title  = {The average distance problem with an Euler elastica penalization},
  author = {Qiang Du and Xin Yang Lu and Chong Wang},
  journal= {arXiv preprint arXiv:2201.10097},
  year   = {2022}
}
R2 v1 2026-06-24T09:01:26.155Z