A two-stage approach based on Bayesian deep learning for predicting remaining useful life of rolling element bearings.

Remaining useful life (RUL) prediction of rolling element bearings is critical to maintaining rotating machinery and lowering industrial costs. There are many RUL prediction techniques, but most of them ignore two factors that may have a significant impact on prediction accuracy. One is the detection of the first predicting time (FPT) while the other is the predictive uncertainty. This paper proposes a two-stage approach to incorporating both factors into the prediction process based on Bayesian deep learning (BDL). In stage one, the state change of the bearing is identified and the FPT is determined according to a proposed detection technique. In stage two, RUL prediction is performed according to a new BDL model, and the results provide RUL point estimates and quantification of predictive uncertainty. The proposed two-stage approach has been validated on two publicly available bearing datasets, and the experimental results have demonstrated the effectiveness of the proposed approach in detecting FPT and its superiority over competitive BDL models. • A new prediction framework has been proposed to address two issues in the process of predicting the RUL of bearings. • The two-stage approach achieves health stage division and RUL prediction of bearings by considering their degradation process. • The two-stage approach shows superior performance compared to other approaches on two separate stage tasks. [ABSTRACT FROM AUTHOR]