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Learning to Solve the Quadratic Assignment Problem with Warm-Started MCMC Finetuning

Machine Learning 2026-04-23 v1 Artificial Intelligence Optimization and Control

Abstract

The quadratic assignment problem (QAP) is a fundamental NP-hard task that poses significant challenges for both traditional heuristics and modern learning-based solvers. Existing QAP solvers still struggle to achieve consistently competitive performance across structurally diverse real-world instances. To bridge this performance gap, we propose PLMA, an innovative permutation learning framework. PLMA features an efficient warm-started MCMC finetuning procedure to enhance deployment-time performance, leveraging short Markov chains to anchor the adaptation to the promising regions previously explored. For rapid exploration via MCMC over the permutation space, we design an additive energy-based model (EBM) that enables an O(1)O(1)-time 2-swap Metropolis-Hastings sampling step. Moreover, the neural network used to parameterize the EBM incorporates a scalable and flexible cross-graph attention mechanism to model interactions between facilities and locations in the QAP. Extensive experiments demonstrate that PLMA consistently outperforms state-of-the-art baselines across various benchmarks. In particular, PLMA achieves a near-zero average optimality gap on QAPLIB, exhibits remarkably superior robustness on the notoriously difficult Taixxeyy instances, and also serves as an effective QAP solver in bandwidth minimization.

Keywords

Cite

@article{arxiv.2604.20109,
  title  = {Learning to Solve the Quadratic Assignment Problem with Warm-Started MCMC Finetuning},
  author = {Yicheng Pan and Ruisong Zhou and Haijun Zou and Tianyou Li and Zaiwen Wen},
  journal= {arXiv preprint arXiv:2604.20109},
  year   = {2026}
}
R2 v1 2026-07-01T12:29:35.849Z