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Minimum 0-Extension Problems on Directed Metrics

Discrete Mathematics 2024-01-05 v2 Optimization and Control

Abstract

For a metric μ\mu on a finite set TT, the minimum 0-extension problem 0-Ext[μ][\mu] is defined as follows: Given VTV\supseteq T and  c:(V2)Q+\ c:{V \choose 2}\rightarrow \mathbf{Q_+}, minimize c(xy)μ(γ(x),γ(y))\sum c(xy)\mu(\gamma(x),\gamma(y)) subject to γ:VT, γ(t)=t (tT)\gamma:V\rightarrow T,\ \gamma(t)=t\ (\forall t\in T), where the sum is taken over all unordered pairs in VV. This problem generalizes several classical combinatorial optimization problems such as the minimum cut problem or the multiterminal cut problem. Karzanov and Hirai established a complete classification of metrics μ\mu for which 0-Ext[μ][\mu] is polynomial time solvable or NP-hard. This result can also be viewed as a sharpening of the general dichotomy theorem for finite-valued CSPs (Thapper and \v{Z}ivn\'{y} 2016) specialized to 0-Ext[μ][\mu]. In this paper, we consider a directed version 0\overrightarrow{0}-Ext[μ][\mu] of the minimum 0-extension problem, where μ\mu and cc are not assumed to be symmetric. We extend the NP-hardness condition of 0-Ext[μ][\mu] to 0\overrightarrow{0}-Ext[μ][\mu]: If μ\mu cannot be represented as the shortest path metric of an orientable modular graph with an orbit-invariant ``directed'' edge-length, then 0\overrightarrow{0}-Ext[μ][\mu] is NP-hard. We also show a partial converse: If μ\mu is a directed metric of a modular lattice with an orbit-invariant directed edge-length, then 0\overrightarrow{0}-Ext[μ][\mu] is tractable. We further provide a new NP-hardness condition characteristic of 0\overrightarrow{0}-Ext[μ][\mu], and establish a dichotomy for the case where μ\mu is a directed metric of a star.

Cite

@article{arxiv.2006.00153,
  title  = {Minimum 0-Extension Problems on Directed Metrics},
  author = {Hiroshi Hirai and Ryuhei Mizutani},
  journal= {arXiv preprint arXiv:2006.00153},
  year   = {2024}
}
R2 v1 2026-06-23T15:55:27.954Z