English

Steiner trees and higher geodecity

Combinatorics 2017-03-30 v1

Abstract

Let GG be a connected graph and :E(G)R+\ell : E(G) \to \mathbb{R}^+ a length-function on the edges of GG. The Steiner distance sdG(A)\mathrm{sd}_G(A) of AV(G)A \subseteq V(G) within GG is the minimum length of a connected subgraph of GG containing AA, where the length of a subgraph is the sum of the lengths of its edges. It is clear that every subgraph HGH \subseteq G, with the induced length-function E(H)\ell|_{E(H)}, satisfies sdH(A)sdG(A)\mathrm{sd}_H(A) \geq \mathrm{sd}_G(A) for every AV(H)A \subseteq V(H). We call HGH \subseteq G kk-geodesic in GG if equality is attained for every AV(H)A \subseteq V(H) with Ak|A| \leq k. A subgraph is fully geodesic if it is kk-geodesic for every kNk \in \mathbb{N}. It is easy to construct examples of graphs HGH \subseteq G such that HH is kk-geodesic, but not (k+1)(k+1)-geodesic, so this defines a strict hierarchy of properties. We are interested in situations in which this hierarchy collapses in the sense that if HGH \subseteq G is kk-geodesic, then HH is already fully geodesic in GG. Our first result of this kind asserts that if TT is a tree and TGT \subseteq G is 2-geodesic with respect to some length-function \ell, then it is fully geodesic. This fails for graphs containing a cycle. We also prove that if CC is a cycle and CGC \subseteq G is 6-geodesic, then CC is fully geodesic. We present an example showing that the number six is indeed optimal. We then develop a structural approach towards a more general theory and present several open questions concerning the big picture underlying this phenomenon.

Keywords

Cite

@article{arxiv.1703.09969,
  title  = {Steiner trees and higher geodecity},
  author = {Daniel Weißauer},
  journal= {arXiv preprint arXiv:1703.09969},
  year   = {2017}
}
R2 v1 2026-06-22T19:00:40.265Z