Wang, K.; Wu, P.; Lou, S.; Pan, H.; Gao, J. Fault Detection-Based Multiple Local Manifold Learning and Its Application to Blast Furnace Ironmaking Process. Electronics2023, 12, 4773.
Wang, K.; Wu, P.; Lou, S.; Pan, H.; Gao, J. Fault Detection-Based Multiple Local Manifold Learning and Its Application to Blast Furnace Ironmaking Process. Electronics 2023, 12, 4773.
Wang, K.; Wu, P.; Lou, S.; Pan, H.; Gao, J. Fault Detection-Based Multiple Local Manifold Learning and Its Application to Blast Furnace Ironmaking Process. Electronics2023, 12, 4773.
Wang, K.; Wu, P.; Lou, S.; Pan, H.; Gao, J. Fault Detection-Based Multiple Local Manifold Learning and Its Application to Blast Furnace Ironmaking Process. Electronics 2023, 12, 4773.
Abstract
Process safety plays a vital role in the modern process industry. To prevent undesired accidents caused by malfunctions or other disturbances in complex industrial processes, considerable attention has been paid to data-driven fault detection techniques. To explore the underlying manifold structure, manifold learning methods including Laplacian eigenmaps, locally linear embedding, and Hessian eigenmaps have been utilized in data-driven fault detection. However, only the partial local structure information is extracted from the aforementioned methods. In this paper, these typical manifold learning methods are synthesized to find the underlying manifold structure from different angles. A more comprehensive local structure is discovered under a unified framework by constructing an objection optimization function for dimension reduction of the process data. The proposed method takes advantage of different manifold learning methods. Based on the proposed dimension reduction method, a new data-driven fault detection method is developed. Hotelling’s T2 and Q statistics are established for the purpose of fault detection. Experiments on an industrial benchmark Tennessee Eastman process and a real blast furnace ironmaking process are carried out to demonstrate the superiority and effectiveness of the proposed method.
Keywords
Data-driven method; Fault detection; Manifold Learning; Blast Furnace Ironmaking Process
Subject
Engineering, Electrical and Electronic Engineering
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
