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arxiv 2102.01378 v1 pith:EB3RK7Q7 submitted 2021-02-02 cs.DS

Multilevel Hypergraph Partitioning with Vertex Weights Revisited

classification cs.DS
keywords hypergraphpartitioningvertexbalancebalancedinstancesproblemweights
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The balanced hypergraph partitioning problem (HGP) is to partition the vertex set of a hypergraph into k disjoint blocks of bounded weight, while minimizing an objective function defined on the hyperedges. Whereas real-world applications often use vertex and edge weights to accurately model the underlying problem, the HGP research community commonly works with unweighted instances. In this paper, we argue that, in the presence of vertex weights, current balance constraint definitions either yield infeasible partitioning problems or allow unnecessarily large imbalances and propose a new definition that overcomes these problems. We show that state-of-the-art hypergraph partitioners often struggle considerably with weighted instances and tight balance constraints (even with our new balance definition). Thus, we present a recursive-bipartitioning technique that is able to reliably compute balanced (and hence feasible) solutions. The proposed method balances the partition by pre-assigning a small subset of the heaviest vertices to the two blocks of each bipartition (using an algorithm originally developed for the job scheduling problem) and optimizes the actual partitioning objective on the remaining vertices. We integrate our algorithm into the multilevel hypergraph partitioner KaHyPar and show that our approach is able to compute balanced partitions of high quality on a diverse set of benchmark instances.

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  1. Fundamental Limits of Hypergraph Edge Partitioning under Independent Edge Sampling

    cs.IT 2026-06 unverdicted novelty 7.0

    The minimal achievable vertex footprint for hypergraph edge partitioning under independent edge sampling is (1/(2√2)) n / N^{1/d}, with a deterministic partitioner achieving it up to a small constant factor.