English

Symmetric Submodular Functions, Uncrossable Functions, and Structural Submodularity

Discrete Mathematics 2026-01-05 v1

Abstract

Diestel, et al. (see Order 35 (2017), JCT-A 167 (2019), arXiv:1805.01439) introduced the notion of abstract separation systems that satisfy a submodularity property, and they call this structural submodularity. Williamson, Goemans, Mihail, and Vazirani (Combinatorica 15 (1995)) call a family of sets F\mathcal{F} uncrossable if the following holds: for any pair of sets A,BFA,B\in\mathcal{F}, both AB,ABA\cap{B},A\cup{B} are in F\mathcal{F}, or both AB,BAA-B,B-A are in F\mathcal{F}. Bansal, Cheriyan, Grout, and Ibrahimpur (Algorithmica 86 (2024), arXiv:2209.11209) call a family of sets F\mathcal{F} pliable if the following holds: for any pair of sets A,BFA,B\in\mathcal{F}, at least two of the sets AB,AB,AB,BAA\cap{B},A\cup{B},A-B,B-A are in F\mathcal{F}. We say that a pliable family of sets F\mathcal{F} satisfies structural submodularity if the following holds: for any pair of crossing sets A,BFA,B\in\mathcal{F}, at least one of the sets AB,ABA\cap{B},A\cup{B} is in F\mathcal{F}, and at least one of the sets AB,BAA-B,B-A is in F\mathcal{F}. For any positive integer d2d\geq2, we construct a pliable family of sets F\mathcal{F} that satisfies structural submodularity such that (a) there do not exist a symmetric submodular function gg and λQ\lambda\in{\mathbb Q} such that F={S:g(S)<λ}\mathcal{F} = \{ S \,:\, g(S)<\lambda \}, and (b) F\mathcal{F} cannot be partitioned into dd (or fewer) uncrossable families.

Keywords

Cite

@article{arxiv.2601.00140,
  title  = {Symmetric Submodular Functions, Uncrossable Functions, and Structural Submodularity},
  author = {Miles Simmons and Ishan Bansal and Joe Cheriyan},
  journal= {arXiv preprint arXiv:2601.00140},
  year   = {2026}
}
R2 v1 2026-07-01T08:47:32.262Z