Industrial process fault detection and diagnosis framework based on enhanced supervised kernel entropy component analysis

Most existing industrial process fault detection and diagnosis (FDD) techniques operate on data collected at a single scale and focus only on known faults. However, actual process data are inherently multiscale and unknown faults are always inevitable during system running. Therefore, they may perform unsatisfactorily. To tackle this problem, this paper develops a decentralized industrial process FDD framework using multiple enhanced supervised kernel entropy component analysis (enhanced SKECA) models, where each model acts as a fault indicator for one specific fault. Faults can be easily diagnosed by monitoring the outputs of all models within the framework. In particular, when new faults are identified, the framework can update itself only by adding the corresponding enhanced SKECA models without a complete rebuilding process. The monitoring results for the continuous stirred tank reactor (CSTR) process show that the proposed framework is effective in diagnosing both known and unknown faults.

Automated summary

Traditional industrial process fault detection and diagnosis techniques are not satisfactory. This paper proposes a decentralized framework using multiple enhanced supervised kernel entropy component analysis models as fault indicators, which can easily diagnose both known and unknown faults.