The transfer learning of uncertainty quantification for industrial plant fault diagnosis system design

J. Blair*, O. Amin, B. D. Brown, S. McArthur, A. Forbes, B. Stephen

*Corresponding author for this work

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Abstract

The performance and confidence in fault detection and diagnostic systems can be undermined by data pipelines that feature multiple compounding sources of uncertainty. These issues further inhibit the deployment of data-based analytics in industry, where variable data quality and lack of confidence in model outputs are already barriers to their adoption. The methodology proposed in this paper supports trustworthy data pipeline design and leverages knowledge gained from one fully-observed data pipeline to a similar, under-observed case. The transfer of uncertainties provides insight into uncertainty drivers without repeating the computational or cost overhead of fully redesigning the pipeline. A SHAP-based human-readable explainable AI (XAI) framework was used to rank and explain the impact of each choice in a data pipeline, allowing the decoupling of positive and negative performance drivers to facilitate the successful selection of highly-performing pipelines. This empirical approach is demonstrated in bearing fault classification case studies using well-understood open-source data.
Original languageEnglish
Article numbere41
Number of pages19
JournalData-Centric Engineering
Volume5
DOIs
Publication statusPublished - 13 Dec 2024

Keywords

  • fault diagnosis
  • fault detection
  • uncertainty

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