English

Forecasting remaining useful life: Interpretable deep learning approach via variational Bayesian inferences

Machine Learning 2019-07-22 v2 Machine Learning

Abstract

Predicting the remaining useful life of machinery, infrastructure, or other equipment can facilitate preemptive maintenance decisions, whereby a failure is prevented through timely repair or replacement. This allows for a better decision support by considering the anticipated time-to-failure and thus promises to reduce costs. Here a common baseline may be derived by fitting a probability density function to past lifetimes and then utilizing the (conditional) expected remaining useful life as a prognostic. This approach finds widespread use in practice because of its high explanatory power. A more accurate alternative is promised by machine learning, where forecasts incorporate deterioration processes and environmental variables through sensor data. However, machine learning largely functions as a black-box method and its forecasts thus forfeit most of the desired interpretability. As our primary contribution, we propose a structured-effect neural network for predicting the remaining useful life which combines the favorable properties of both approaches: its key innovation is that it offers both a high accountability and the flexibility of deep learning. The parameters are estimated via variational Bayesian inferences. The different approaches are compared based on the actual time-to-failure for aircraft engines. This demonstrates the performance and superior interpretability of our method, while we finally discuss implications for decision support.

Keywords

Cite

@article{arxiv.1907.05146,
  title  = {Forecasting remaining useful life: Interpretable deep learning approach via variational Bayesian inferences},
  author = {Mathias Kraus and Stefan Feuerriegel},
  journal= {arXiv preprint arXiv:1907.05146},
  year   = {2019}
}
R2 v1 2026-06-23T10:18:21.886Z