BRB Prediction With Customized Attributes Weights and Tradeoff Analysis for Concurrent Fault Diagnosis

Abstract

Comprised of multiple belief rules that are close to human knowledge representation, the belief rule base (BRB) has the ability to make full use of both data obtained from historic records and experts’ knowledge under uncertainty. When applied in fault diagnosis, the final diagnostic results are inferred by first activating the matching degrees and activation weights, and then integrating the activated rules with the evidential reasoning algorithm. In this study, a novel BRB prediction approach is proposed for concurrent fault diagnosis. In the proposed approach, the indicative factors are modeled as attributes with customized attribute weights to represent their relevance to a known system fault and vice versa. Second, a tradeoff analysis is conducted by comparing the beliefs for different faults. The diagnosed faults with bigger beliefs within a predetermined valve would be considered as concurrent faults. To further improve the prediction accuracy, an optimization approach with the differential evolutionary algorithm as the optimization engine is designed with model constraints reflecting the complex correlations between the indicative factors and concurrent faults. A marine diesel engine fault diagnosis case is studied for validation. Case study results show that: first, both single and concurrent faults can be diagnosed with high accuracy by the proposed BRB prediction approach; second, the BRBs with optimized attributes weights has shown superior performance than with equal and fixed attribute weights; and third, the new BRB prediction approach outperforms the previous approach with multiple sub-BRBs as well as other approaches to achieve a higher modeling accuracy.