English

A fractal shape optimization problem in branched transport

Optimization and Control 2018-01-01 v2 Classical Analysis and ODEs

Abstract

We investigate the following question: what is the set of unit volume which can be best irrigated starting from a single source at the origin, in the sense of branched transport? We may formulate this question as a shape optimization problem and prove existence of solutions, which can be considered as a sort of "unit ball" for branched transport. We establish some elementary properties of optimizers and describe these optimal sets A as sublevel sets of a so-called landscape function which is now classical in branched transport. We prove β\beta-H{\"o}lder regularity of the landscape function, allowing us to get an upper bound on the Minkowski dimension of the boundary: dim \partialA \le d -- β\beta (where β\beta := d(α\alpha -- (1 -- 1/d)) \in (0, 1) is a relevant exponent in branched transport, associated with the exponent α\alpha > 1 -- 1/d appearing in the cost). We are not able to prove the upper bound, but we conjecture that \partialA is of non-integer dimension d -- β\beta. Finally, we make an attempt to compute numerically an optimal shape, using an adaptation of the phase-field approximation of branched transport introduced some years ago by Oudet and the second author.

Keywords

Cite

@article{arxiv.1709.01415,
  title  = {A fractal shape optimization problem in branched transport},
  author = {Paul Pegon and Filippo Santambrogio and Qinglan Xia},
  journal= {arXiv preprint arXiv:1709.01415},
  year   = {2018}
}
R2 v1 2026-06-22T21:33:37.884Z