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Main Authors: Zhang, Yiqun, Huang, Zhanpei, Zhao, Mingjie, Zhang, Chuyao, Lu, Yang, Ji, Yuzhu, Gu, Fangqing, Zeng, An
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.06757
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author Zhang, Yiqun
Huang, Zhanpei
Zhao, Mingjie
Zhang, Chuyao
Lu, Yang
Ji, Yuzhu
Gu, Fangqing
Zeng, An
author_facet Zhang, Yiqun
Huang, Zhanpei
Zhao, Mingjie
Zhang, Chuyao
Lu, Yang
Ji, Yuzhu
Gu, Fangqing
Zeng, An
contents Unlabeled streaming data are usually collected to describe dynamic systems, where concept drift detection is a vital prerequisite to understanding the evolution of systems. However, the drifting concepts are usually imbalanced in most real cases, which brings great challenges to drift detection. That is, the dominant statistics of large clusters can easily mask the drifting of small cluster distributions (also called small concepts), which is known as the `masking effect'. Considering that most existing approaches only detect the overall existence of drift under the assumption of balanced concepts, two critical problems arise: 1) where the small concept is, and 2) how to detect its drift. To address the challenging concept drift detection for imbalanced data, we propose Imbalanced Cluster Descriptor-based Drift Detection (ICD3) approach that is unbiased to the imbalanced concepts. This approach first detects imbalanced concepts by employing a newly designed multi-distribution-granular search, which ensures that the distribution of both small and large concepts is effectively captured. Subsequently, it trains a One-Cluster Classifier (OCC) for each identified concept to carefully monitor their potential drifts in the upcoming data chunks. Since the detection is independently performed for each concept, the dominance of large clusters is thus circumvented. ICD3 demonstrates highly interpretability by specifically locating the drifted concepts, and is robust to the changing of the imbalance ratio of concepts. Comprehensive experiments with multi-aspect ablation studies conducted on various benchmark datasets demonstrate the superiority of ICD3 against the state-of-the-art counterparts.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06757
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning Unbiased Cluster Descriptors for Interpretable Imbalanced Concept Drift Detection
Zhang, Yiqun
Huang, Zhanpei
Zhao, Mingjie
Zhang, Chuyao
Lu, Yang
Ji, Yuzhu
Gu, Fangqing
Zeng, An
Machine Learning
Artificial Intelligence
Unlabeled streaming data are usually collected to describe dynamic systems, where concept drift detection is a vital prerequisite to understanding the evolution of systems. However, the drifting concepts are usually imbalanced in most real cases, which brings great challenges to drift detection. That is, the dominant statistics of large clusters can easily mask the drifting of small cluster distributions (also called small concepts), which is known as the `masking effect'. Considering that most existing approaches only detect the overall existence of drift under the assumption of balanced concepts, two critical problems arise: 1) where the small concept is, and 2) how to detect its drift. To address the challenging concept drift detection for imbalanced data, we propose Imbalanced Cluster Descriptor-based Drift Detection (ICD3) approach that is unbiased to the imbalanced concepts. This approach first detects imbalanced concepts by employing a newly designed multi-distribution-granular search, which ensures that the distribution of both small and large concepts is effectively captured. Subsequently, it trains a One-Cluster Classifier (OCC) for each identified concept to carefully monitor their potential drifts in the upcoming data chunks. Since the detection is independently performed for each concept, the dominance of large clusters is thus circumvented. ICD3 demonstrates highly interpretability by specifically locating the drifted concepts, and is robust to the changing of the imbalance ratio of concepts. Comprehensive experiments with multi-aspect ablation studies conducted on various benchmark datasets demonstrate the superiority of ICD3 against the state-of-the-art counterparts.
title Learning Unbiased Cluster Descriptors for Interpretable Imbalanced Concept Drift Detection
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.06757