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Toward Reduction in False Positives Just-In-Time Software Defect Prediction Using Deep Reinforcement Learning

Ahmad Muhaimin Ismail, Siti Hafizah Ab Hamid, Asmiza Abdul Sani, Nur Nasuha Daud

2024IEEE Access15 citationsDOIOpen Access PDF

Abstract

Deep Q-Network (DQN) is a popular deep reinforcement learning algorithm that has demonstrated promising results across a variety of domains. DQN presents a promising solution to the challenge of lowering false positives in software defect prediction, thereby enhancing the reliability of the prediction performance. In software defect prediction, false positives occur when the prediction model incorrectly predicts code changes to be defective. Consequently, developers waste time and resources on non-existent defects. This paper advocates for employing DQN in software defect prediction, focusing on minimizing false positives and maximizing the prediction performance. Throughout the training phase, the model learns to predict defect-prone following a reward policy aimed at reducing false results. Experimental findings show that the proposed DQN outperforms baseline classifier, improving the prediction accuracy of true defects by up to 27% when using only 20% efforts. The results show that the effectiveness of DQN in tackling false positives, thereby emphasizing the significance of incorporating dynamic reward in predicting software defects.

Topics & Concepts

False positive paradoxComputer scienceArtificial intelligenceClassifier (UML)Reinforcement learningMachine learningSoftwareReduction (mathematics)False positives and false negativesData miningMathematicsGeometryProgramming languageSoftware Engineering ResearchSoftware Reliability and Analysis ResearchAdvanced Malware Detection Techniques
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