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POMO: Policy Optimization with Multiple Optima for Reinforcement Learning

Machine Learning 2021-07-14 v3

Abstract

In neural combinatorial optimization (CO), reinforcement learning (RL) can turn a deep neural net into a fast, powerful heuristic solver of NP-hard problems. This approach has a great potential in practical applications because it allows near-optimal solutions to be found without expert guides armed with substantial domain knowledge. We introduce Policy Optimization with Multiple Optima (POMO), an end-to-end approach for building such a heuristic solver. POMO is applicable to a wide range of CO problems. It is designed to exploit the symmetries in the representation of a CO solution. POMO uses a modified REINFORCE algorithm that forces diverse rollouts towards all optimal solutions. Empirically, the low-variance baseline of POMO makes RL training fast and stable, and it is more resistant to local minima compared to previous approaches. We also introduce a new augmentation-based inference method, which accompanies POMO nicely. We demonstrate the effectiveness of POMO by solving three popular NP-hard problems, namely, traveling salesman (TSP), capacitated vehicle routing (CVRP), and 0-1 knapsack (KP). For all three, our solver based on POMO shows a significant improvement in performance over all recent learned heuristics. In particular, we achieve the optimality gap of 0.14% with TSP100 while reducing inference time by more than an order of magnitude.

Keywords

Cite

@article{arxiv.2010.16011,
  title  = {POMO: Policy Optimization with Multiple Optima for Reinforcement Learning},
  author = {Yeong-Dae Kwon and Jinho Choo and Byoungjip Kim and Iljoo Yoon and Youngjune Gwon and Seungjai Min},
  journal= {arXiv preprint arXiv:2010.16011},
  year   = {2021}
}

Comments

Accepted at NeurIPS 2020

R2 v1 2026-06-23T19:45:55.181Z