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Dynamic Ensemble Selection for Imbalanced Data Streams With Concept Drift.

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    This study introduces a dynamic ensemble selection for imbalanced data streams with concept drift (DES-ICD). The method effectively handles concept drift and class imbalance, improving classification accuracy for minority instances in data streams.

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    Area of Science:

    • Machine Learning
    • Data Mining
    • Artificial Intelligence

    Background:

    • Ensemble learning typically uses global performance for base classifier selection, which is inadequate for localized concept drift.
    • Data streams often present class imbalance, negatively impacting ensemble learning accuracy for minority classes.

    Purpose of the Study:

    • To propose a dynamic ensemble selection for imbalanced data streams with concept drift (DES-ICD).
    • To address the limitations of global performance criteria and class imbalance in ensemble learning for data streams.

    Main Methods:

    • A novel synthetic minority oversampling technique with adaptive nearest neighbors (AnnSMOTE) is developed to generate minority instances for new concepts.
    • DES-ICD builds base classifiers on AnnSMOTE-balanced data chunks and merges them into a candidate pool.
    • Optimal classifier combinations are selected based on neighborhood performance for query instances.

    Main Results:

    • The proposed DES-ICD method demonstrated superior performance over seven comparative methods.
    • Experimental results on nine synthetic and five real-world datasets confirmed improved classification accuracy.
    • The method accurately tracks new concepts in imbalanced data streams.

    Conclusions:

    • DES-ICD effectively addresses concept drift and class imbalance in data streams.
    • The neighborhood-based selection strategy enhances the adaptability of ensemble models.
    • The AnnSMOTE technique improves the handling of minority instances in evolving data.