English

Hardness and Approximation of Submodular Minimum Linear Ordering Problems

Data Structures and Algorithms 2023-10-30 v2 Computational Complexity

Abstract

The minimum linear ordering problem (MLOP) generalizes well-known combinatorial optimization problems such as minimum linear arrangement and minimum sum set cover. MLOP seeks to minimize an aggregated cost f()f(\cdot) due to an ordering σ\sigma of the items (say [n][n]), i.e., minσi[n]f(Ei,σ)\min_{\sigma} \sum_{i\in [n]} f(E_{i,\sigma}), where Ei,σE_{i,\sigma} is the set of items mapped by σ\sigma to indices [i][i]. Despite an extensive literature on MLOP variants and approximations for these, it was unclear whether the graphic matroid MLOP was NP-hard. We settle this question through non-trivial reductions from mininimum latency vertex cover and minimum sum vertex cover problems. We further propose a new combinatorial algorithm for approximating monotone submodular MLOP, using the theory of principal partitions. This is in contrast to the rounding algorithm by Iwata, Tetali, and Tripathi [ITT2012], using Lov\'asz extension of submodular functions. We show a (21+f1+E)(2-\frac{1+\ell_{f}}{1+|E|})-approximation for monotone submodular MLOP where f=f(E)maxxEf({x})\ell_{f}=\frac{f(E)}{\max_{x\in E}f(\{x\})} satisfies 1fE1 \leq \ell_f \leq |E|. Our theory provides new approximation bounds for special cases of the problem, in particular a (21+r(E)1+E)(2-\frac{1+r(E)}{1+|E|})-approximation for the matroid MLOP, where f=rf = r is the rank function of a matroid. We further show that minimum latency vertex cover (MLVC) is 43\frac{4}{3}-approximable, by which we also lower bound the integrality gap of its natural LP relaxation, which might be of independent interest.

Keywords

Cite

@article{arxiv.2108.00914,
  title  = {Hardness and Approximation of Submodular Minimum Linear Ordering Problems},
  author = {Majid Farhadi and Swati Gupta and Shengding Sun and Prasad Tetali and Michael C. Wigal},
  journal= {arXiv preprint arXiv:2108.00914},
  year   = {2023}
}
R2 v1 2026-06-24T04:45:23.887Z