Windmann, StefanStefanWindmann2022-05-062022-05-062022https://publica.fraunhofer.de/handle/publica/41615310.1109/TASE.2021.3138925This paper presents a novel fault detection approach for industrial batch processes. The batch processes under consideration are characterized by the interaction between discrete system modes and non-stationary continuous dynamics. Therefore, a stochastic hybrid process model (SHPM) is introduced, where process variables are modeled as time-variant Gaussian distributions, which depend on hidden system modes. Transitions between the system modes are assumed to be either autonomous or to be triggered by observable events such as on/off signals. The model parameters are determined from training data using expectation-maximization techniques. A new fault detection algorithm is proposed, which assesses the likelihoods of sensor signals on the basis of the stochastic hybrid process model. Evaluation of the proposed fault detection system has been conducted for a penicillin production process, with the results showing a significant improvement over the existing baseline methods.enbatch production systemscomputational modelingdata modelsFault detectionfault diagnosisHidden Markov Modelsmathematical modelprocess monitoringstochastic processes004670journal article