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    Area of Science:

    • Computer Science
    • Artificial Intelligence
    • Data Visualization

    Background:

    • Tree ensemble classifiers achieve high performance using numerous rules, but this complexity hinders interpretability.
    • Existing model reduction techniques simplify classifiers by extracting rule subsets, often losing crucial information and ignoring infrequent but important anomalous rules.

    Purpose of the Study:

    • To develop a scalable visual analysis method for explaining tree ensemble classifiers with tens of thousands of rules.
    • To enhance model interpretability by preserving fidelity and incorporating anomalous rules.

    Main Methods:

    • Adaptive hierarchical organization of rules to maintain comprehensiveness.
    • Anomaly-biased model reduction to prioritize infrequent but critical rules at each level.
    • Matrix-based hierarchical visualization for multi-level exploration of rules.

    Main Results:

    • The proposed method effectively explains tree ensemble classifiers by organizing rules hierarchically.
    • It successfully incorporates and highlights anomalous rules, which are often missed by traditional methods.
    • Quantitative experiments and case studies validate the method's ability to foster a deeper understanding of classifier logic.

    Conclusions:

    • The developed visual analysis method enhances the interpretability of complex tree ensemble models.
    • It achieves this by preserving model fidelity through hierarchical organization and prioritizing anomalous rules.
    • This approach offers a comprehensive understanding of both common and anomalous decision pathways within the classifier.