Abstract
Rule set learning has long been studied and has recently been frequently revisited due to the need for interpretable models. Still, existing methods have several shortcomings: 1) most recent methods require a binary feature matrix as input, while learning rules directly from numeric variables is understudied; 2) existing methods impose orders among rules, either explicitly or implicitly, which harms interpretability; and 3) currently no method exists for learning probabilistic rule sets for multi-class target variables (there is only one for probabilistic rule lists).
We propose Turs, for Truly Unordered Rule Sets, which addresses these shortcomings. We first formalize the problem of learning truly unordered rule sets. To resolve conflicts caused by overlapping rules, i.e., instances covered by multiple rules, we propose a novel approach that exploits the probabilistic properties of our rule sets. We next develop a two-phase heuristic algorithm that learns rule sets by carefully growing rules. An important innovation is that we use a surrogate score to take the global potential of the rule set into account when learning a local rule.
Finally, we empirically demonstrate that, compared to non-probabilistic and (explicitly or implicitly) ordered state-of-the-art methods, our method learns rule sets that not only have better interpretability but also better predictive performance.
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Notes
- 1.
Note that “nestedness” is based on the rules’ covers rather than on their conditions. For instance, if \(S_i\) is \(X_1 <= 1\) and \(S_j\) is \(X_2 <= 1\), \(S_i\) and \(S_j\) could still be nested.
- 2.
The source code is available at https://github.com/ylincen/TURS.
References
Breiman, L., Friedman, J., Stone, C.J., Olshen, R.A.: Classification and Regression Trees. CRC Press, Boca Raton (1984)
Clark, P., Boswell, R.: Rule induction with CN2: some recent improvements. In: Kodratoff, Y. (ed.) EWSL 1991. LNCS, vol. 482, pp. 151–163. Springer, Heidelberg (1991). https://doi.org/10.1007/BFb0017011
Clark, P., Niblett, T.: The CN2 induction algorithm. Mach. Learn. 3(4), 261–283 (1989)
Cohen, W.W.: Fast effective rule induction. In: Machine learning proceedings 1995, pp. 115–123. Elsevier (1995)
Dash, S., Gunluk, O., Wei, D.: Boolean decision rules via column generation. Adv. Neural. Inf. Process. Syst. 31, 4655–4665 (2018)
Frank, E., Witten, I.H.: Generating accurate rule sets without global optimization (1998)
Fürnkranz, J., Flach, P.A.: Roc ‘n’rule learning-towards a better understanding of covering algorithms. Mach. Learn. 58(1), 39–77 (2005)
Fürnkranz, J., Gamberger, D., Lavrač, N.: Foundations of rule learning. Springer Science & Business Media (2012). https://doi.org/10.1007/978-3-540-75197-7
Gay, D., Boullé, M.: A Bayesian approach for classification rule mining in quantitative databases. In: Flach, P.A., De Bie, T., Cristianini, N. (eds.) ECML PKDD 2012. LNCS (LNAI), vol. 7524, pp. 243–259. Springer, Heidelberg (2012). https://doi.org/10.1007/978-3-642-33486-3_16
Grünwald, P., Roos, T.: Minimum description length revisited. Int. J. Math. Ind. 11(01), 1930001 (2019)
Hühn, J., Hüllermeier, E.: FURIA: an algorithm for unordered fuzzy rule induction. Data Min. Knowl. Disc. 19(3), 293–319 (2009)
Lakkaraju, H., Bach, S.H., Leskovec, J.: Interpretable decision sets: a joint framework for description and prediction. In: Proceedings of the 22nd ACM SIGKDD, pp. 1675–1684 (2016)
Liu, B., Hsu, W., Ma, Y., et al.: Integrating classification and association rule mining. In: KDD. vol. 98, pp. 80–86 (1998)
Molnar, C.: Interpretable machine learning. https://www.Lulu.com (2020)
Mononen, T., Myllymäki, P.: Computing the multinomial stochastic complexity in sub-linear time. In: PGM08, pp. 209–216 (2008)
Murdoch, W.J., Singh, C., Kumbier, K., Abbasi-Asl, R., Yu, B.: Interpretable machine learning: definitions, methods, and applications. arXiv preprint arXiv:1901.04592 (2019)
Proença, H.M., van Leeuwen, M.: Interpretable multiclass classification by mdl-based rule lists. Inf. Sci. 512, 1372–1393 (2020)
Quinlan, J.R.: C4.5: Programs for machine learning. Elsevier (2014)
Van Leeuwen, M., Knobbe, A.: Diverse subgroup set discovery. Data Min. Knowl. Disc. 25(2), 208–242 (2012)
Veloso, A., Meira, W., Zaki, M.J.: Lazy associative classification. In: Sixth International Conference on Data Mining (ICDM’06), pp. 645–654. IEEE (2006)
Wang, T., Rudin, C., Doshi-Velez, F., Liu, Y., Klampfl, E., MacNeille, P.: A bayesian framework for learning rule sets for interpretable classification. J. Mach. Learn. Res. 18(1), 2357–2393 (2017)
Yang, F., et al.: Learning interpretable decision rule sets: a submodular optimization approach. In: Advances in Neural Information Processing Systems, vol. 34 (2021)
Yang, H., Rudin, C., Seltzer, M.: Scalable Bayesian rule lists. In: International Conference on Machine Learning, pp. 3921–3930. PMLR (2017)
Zhang, G., Gionis, A.: Diverse rule sets. In: Proceedings of the 26th ACM SIGKDD, pp. 1532–1541 (2020)
Acknowledgements
We are grateful for the very inspiring feedback from the anonymous reviewers. This work is part of the research programme ‘Human-Guided Data Science by Interactive Model Selection’ with project number 612.001.804, which is (partly) financed by the Dutch Research Council (NWO).
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Yang, L., van Leeuwen, M. (2023). Truly Unordered Probabilistic Rule Sets for Multi-class Classification. In: Amini, MR., Canu, S., Fischer, A., Guns, T., Kralj Novak, P., Tsoumakas, G. (eds) Machine Learning and Knowledge Discovery in Databases. ECML PKDD 2022. Lecture Notes in Computer Science(), vol 13717. Springer, Cham. https://doi.org/10.1007/978-3-031-26419-1_6
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