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Generalization of machine learning for problem reduction: a case study on travelling salesman problems

Author

Listed:
  • Yuan Sun

    (School of Science, RMIT University)

  • Andreas Ernst

    (Monash University)

  • Xiaodong Li

    (School of Science, RMIT University)

  • Jake Weiner

    (School of Science, RMIT University)

Abstract

Combinatorial optimization plays an important role in real-world problem solving. In the big data era, the dimensionality of a combinatorial optimization problem is usually very large, which poses a significant challenge to existing solution methods. In this paper, we examine the generalization capability of a machine learning model for problem reduction on the classic travelling salesman problems (TSP). We demonstrate that our method can greedily remove decision variables from an optimization problem that are predicted not to be part of an optimal solution. More specifically, we investigate our model’s capability to generalize on test instances that have not been seen during the training phase. We consider three scenarios where training and test instances are different in terms of: (1) problem characteristics; (2) problem sizes; and (3) problem types. Our experiments show that this machine learning-based technique can generalize reasonably well over a wide range of TSP test instances with different characteristics or sizes. Since the accuracy of predicting unused variables naturally deteriorates as a test instance is further away from the training set, we observe that, even when tested on a different TSP problem variant, the machine learning model still makes useful predictions about which variables can be eliminated without significantly impacting solution quality.

Suggested Citation

  • Yuan Sun & Andreas Ernst & Xiaodong Li & Jake Weiner, 2021. "Generalization of machine learning for problem reduction: a case study on travelling salesman problems," OR Spectrum: Quantitative Approaches in Management, Springer;Gesellschaft für Operations Research e.V., vol. 43(3), pages 607-633, September.
    • Handle: RePEc:spr:orspec:v:43:y:2021:i:3:d:10.1007_s00291-020-00604-x
    DOI: 10.1007/s00291-020-00604-x
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    References listed on IDEAS

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    1. Balabhaskar Balasundaram & Sergiy Butenko & Illya V. Hicks, 2011. "Clique Relaxations in Social Network Analysis: The Maximum k -Plex Problem," Operations Research, INFORMS, vol. 59(1), pages 133-142, February.
    2. Hanif D. Sherali & Patrick J. Driscoll, 2002. "On Tightening the Relaxations of Miller-Tucker-Zemlin Formulations for Asymmetric Traveling Salesman Problems," Operations Research, INFORMS, vol. 50(4), pages 656-669, August.
    3. Wu, Qinghua & Hao, Jin-Kao, 2015. "A review on algorithms for maximum clique problems," European Journal of Operational Research, Elsevier, vol. 242(3), pages 693-709.
    4. Lembke B., 1918. "√ a. p," Journal of Economics and Statistics (Jahrbuecher fuer Nationaloekonomie und Statistik), De Gruyter, vol. 111(1), pages 709-712, February.
    5. Gerhard Reinelt, 1991. "TSPLIB—A Traveling Salesman Problem Library," INFORMS Journal on Computing, INFORMS, vol. 3(4), pages 376-384, November.
    6. S. Lin & B. W. Kernighan, 1973. "An Effective Heuristic Algorithm for the Traveling-Salesman Problem," Operations Research, INFORMS, vol. 21(2), pages 498-516, April.
    7. Roy Jonker & Ton Volgenant, 1984. "Nonoptimal Edges for the Symmetric Traveling Salesman Problem," Operations Research, INFORMS, vol. 32(4), pages 837-846, August.
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