Deep Learning for Anomaly Detection in Large-Scale Industrial Data
R. Anuradha, B. P. Swathi, Amandeep Nagpal, Prateek Chaturvedi, Ravi Kalra, Adil Abbas Alwan
Abstract
Industrial data has increased significantly in the emerging data-driven age, and it often contains abnormalities that could point to crucial system faults or inefficiencies. The complexity and high dimensionality of the data provide special hurdles for anomaly identification in such large-scale data settings. In this study, a robust deep learning framework for anomaly detection is presented, one that can function with the large and complex datasets that are common in industrial applications. To capture the temporal and spatial relationships present in sensor data, the framework makes use of sophisticated neural network designs, such as convolutional neural networks (CNNs) and recurrent neural networks (RNNs). The suggested model learns the underlying data structure using unsupervised learning, which allows it to recognize variations that may indicate possible abnormalities. An extensive industrial dataset is used to evaluate the system's effectiveness, and the results reveal that the system performs better than conventional machine learning techniques in terms of both computing efficiency and detection accuracy. The flexibility and scalability of the concept are reinforced by its implementation across many industrial sectors, which further demonstrates its adaptability. The present study not only advances the theoretical understanding of anomaly detection mechanisms but also provides industry practitioners with a useful tool to ensure the safety and dependability of industrial operations in the face of increasing data complexity.