Boosting Classifier Performance with Opposition-Based Data Transformation

In this paper, we introduce a novel data transformation framework based on Opposition-Based Learning (OBL) to boost the performance of traditional classification algorithms. Originally developed to accelerate convergence in optimization tasks, OBL is leveraged here to generate synthetic opposite samples that replace the acutely training data and improve decision boundary formation. We explore three OBL variants; Global OBL, Class-Wise OBL, and Localized Class-Wise OBL; and integrate them with several widely used classifiers, including K-Nearest Neighbors (KNN), Support Vector Machines (SVM), Logistic Regression (LR), and Decision Tree (DT). Extensive experiments conducted on 26 heterogeneous and high-dimensional datasets demonstrate that OBL-enhanced classifiers consistently outperform their standard counterparts in terms of accuracy and F1-score, frequently achieving near-perfect or perfect classification. Furthermore, OBL contributes to improved computational efficiency, particularly in SVM and LR. These findings underscore the potential of OBL as a lightweight yet powerful data transformation strategy for enhancing classification performance, especially in complex or sparse learning environments.