Three-layer deep learning network random trees for fault detection in chemical production process
This addresses fault detection for chemical production processes, but it appears incremental as it combines existing deep learning and machine learning methods.
The paper tackles fault detection in complex chemical production processes by proposing a three-layer deep learning network random trees model, which integrates deep learning for feature extraction and machine learning for classification, and experimental results on the Tennessee Eastman process verify its superiority.
With the development of technology, the chemical production process is becoming increasingly complex and large-scale, making fault detection particularly important. However, current detective methods struggle to address the complexities of large-scale production processes. In this paper, we integrate the strengths of deep learning and machine learning technologies, combining the advantages of bidirectional long and short-term memory neural networks, fully connected neural networks, and the extra trees algorithm to propose a novel fault detection model named three-layer deep learning network random trees (TDLN-trees). First, the deep learning component extracts temporal features from industrial data, combining and transforming them into a higher-level data representation. Second, the machine learning component processes and classifies the features extracted in the first step. An experimental analysis based on the Tennessee Eastman process verifies the superiority of the proposed method.