Abstract
Process monitoring techniques in chemical process systems help to improve product quality and plant safety. Multiscale classification plays a crucial role in the monitoring of chemical processes. However, there is a problem in coping with high-dimensional correlated data produced by complex, nonlinear processes. Therefore, an improved multiscale fault classification framework has been proposed to enhance the fault classification ability in nonlinear chemical process systems. This framework combines wavelet transform (WT), kernel principal component analysis (KPCA), and K nearest neighbors (KNN) classifier. Initially, a moving window-based WT is used to extract multiscale information from process data in time and frequency simultaneously at different scales. The resulting wavelet coefficients are reconstructed and fed into the KPCA to produce feature vectors. In the final step, these vectors have been used as inputs for the KNN classifier. The performance of the proposed multi-scale KPCA-KNN framework is analyzed and compared using a continuous stirred tank reactor (CSTR) system as a case study. The results show that the proposed multiscale KPCA-KNN framework has a high success rate over PCA-KNN and KPCA-KNN methods.
Highlights
Process monitoring is essential for ensuring consistent product quality and safety in chemical process systems
This paper proposes a new fault classification framework using a wavelet-based multiscale kernel principal component analysis (KPCA) and K nearest neighbors (KNN) classifier
As control of continuous stirred tank reactor (CSTR) is a challenging problem, several researchers often use CSTR to evaluate the effectiveness of process monitoring techniques
Summary
Process monitoring is essential for ensuring consistent product quality and safety in chemical process systems. The root causes of process faults should be identified earlier so the system can be restored to its normal operating conditions by corrective measures. Wavelet transform (WT) is usually used in multi-scale process monitoring to decompose original process data into multi-scale components. WT provides many advantages over traditional single-scale techniques since it distinguishes deterministic and stochastic features from the process's initial measurements [21, 22]. This allows for a more meaningful interpretation of the process phenomena in their time-frequency bands [23]. The scaled version of the original signal is achieved by projecting it on an orthonormal basis function family represented as φij (t) = 2− j/2φ(2− j/2 t − s)
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