Integrating Data Mining Techniques into Robotic Systems: An Analytical Study Towards Developing Intelligent Performance
DOI:
https://doi.org/10.65591/fambqf60Keywords:
Artificial Intelligence, Data Mining, Robotic Systems, Social RobotsAbstract
In recent years, the convergence of data mining and robotic systems has emerged as a key trend shaping the future of artificial intelligence. This study aimed to explore how data mining techniques can enhance robotic decision-making, enabling robots to learn, adapt, and respond to dynamic environments. A qualitative-analytical research design was used to examine the impact of intelligent data processing on robotic behavior, particularly in social robots. The analysis revealed that real-time data mining significantly improves robot autonomy, adaptability, and human interaction. Moreover, the integration of data mining introduced critical security challenges, such as distributed denial of service (DoS) attacks, sensor data eavesdropping, and manipulation of input data. The study found that implementing advanced security mechanisms—including encryption, authentication, and anomaly detection through artificial intelligence algorithms—helps mitigate these risks effectively. The findings emphasize the transition from task-executing machines to intelligent systems capable of independent decision-making. One notable application discussed in the paper is the development of social robots that interact naturally and empathetically with humans. This research highlights the importance of embedding data mining within robotic architectures not only to enhance performance but also to strengthen security and resilience. The study concludes that the intelligent fusion of data mining and robotics paves the way for scalable, secure, and context-aware robotic systems. Future work is needed to explore real-world implementations and evaluate long-term performance under various operational scenarios.
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Copyright (c) 2026 Hasanain Al-Rzoky (Author)
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