English

Improved Hardness and Approximations for Cardinality-Based Minimum $s$-$t$ Cuts Problems in Hypergraphs

Computational Complexity 2025-04-08 v3 Data Structures and Algorithms

Abstract

In hypergraphs, an edge that crosses a cut (i.e., a bipartition of nodes) can be split in several ways, depending on how many nodes are placed on each side of the cut. A cardinality-based splitting function assigns a nonnegative cost of wiw_i for each cut hyperedge ee with exactly ii nodes on the side of the cut that contains the minority of nodes from ee. The cardinality-based minimum ss-tt cut aims to find an ss-tt cut with minimum total cost. We answer a recently posed open question by proving that the problem becomes NP-hard outside the submodular region shown by~\cite{veldt2022hypergraph}. Our result also holds for rr-uniform hypergraphs with r4r \geq 4. Specifically for 44-uniform hypergraphs we show that the problem is NP-hard for all w2>2w_2 > 2, and additionally prove that the No-Even-Split problem is NP-hard. We then turn our attention to approximation strategies and approximation hardness results in the non-submodular case. We design a strategy for projecting non-submodular penalties to the submodular region, which we prove gives the optimal approximation among all such projection strategies. We also show that alternative approaches are unlikely to provide improved guarantees, by showing matching approximation hardness bounds assuming the Unique Games Conjecture and asymptotically tight approximation hardness bounds assuming PNP\text{P} \neq \text{NP}.

Keywords

Cite

@article{arxiv.2409.07201,
  title  = {Improved Hardness and Approximations for Cardinality-Based Minimum $s$-$t$ Cuts Problems in Hypergraphs},
  author = {Florian Adriaens and Vedangi Bengali and Iiro Kumpulainen and Nikolaj Tatti and Nate Veldt},
  journal= {arXiv preprint arXiv:2409.07201},
  year   = {2025}
}
R2 v1 2026-06-28T18:41:01.257Z