A framework for data-driven fault detection and identification with multiscale kernel fisher discriminant analysis in chemical process systems / Norazwan Md Nor
Fault detection and identification (FDI) framework plays an important role to ensure consistent and reliable operation of chemical process systems. The FDI framework has two main tasks, namely to detect the presence of a fault and to classify the location and type of the fault. In most cases, it...
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| Format: | Thesis |
| Published: |
2018
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| Subjects: | |
| Online Access: | http://studentsrepo.um.edu.my/9357/1/Norazwan_Md_Nor.pdf http://studentsrepo.um.edu.my/9357/6/norazwan.pdf http://studentsrepo.um.edu.my/9357/ |
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| Summary: | Fault detection and identification (FDI) framework plays an important role to ensure
consistent and reliable operation of chemical process systems. The FDI framework has
two main tasks, namely to detect the presence of a fault and to classify the location and
type of the fault. In most cases, it is impractical to develop precise model from first
principles as it requires the involvement of process complex physics and the interactions
among the different components creating the process. Therefore, data-driven FDI
methods, which can make use of process data to capture their trends and dynamics,
provide an attractive alternative for the quick development and deployment of FDI
solutions. One of the main objectives of this thesis is to develop a hybrid framework for
data-driven FDI in chemical process systems. This framework integrated a novel multiscale
dimensional reduction method for pre-processing step and an improved datadriven
FDI framework. This thesis focuses on proposing a dimensionality reduction
method based on multi-scale kernel Fisher discriminant analysis (multi-scale KFDA), in
which discrete wavelet transform (DWT) was combined with kernel Fisher discriminant
analysis (KFDA) method. Initially, DWT was applied to extract the dynamics of the
process at different scales. The wavelet coefficients obtained during the analysis were
reconstructed using the inverse discrete wavelet transform (IDWT) method and then,
they were fed into the KFDA to produce discriminant vectors. Finally, the discriminant
vectors were used as inputs for the classification task in fault identification step. Apart
from that, complete fault identification procedures based on adaptive neuro-fuzzy
inference system (ANFIS), support vector machine (SVM), Gaussian mixture model
(GMM), and k-nearest neighbor (kNN) were developed to investigate the parameters that could be optimised for better fault identification. Furthermore, this thesis extended
the proposed multi-scale KFDA-based fault identification methods to a hybrid datadriven
FDI framework. In the hybrid FDI framework, all classification methods used
previously were combined into a single classification framework. Hence, a complete
data-driven hybridisation FDI framework for chemical process systems was proposed
and analysed. The proposed FDI frameworks were applied in three different chemical
processes: the simulation of Tennessee Eastman process, the fed-batch penicillin
fermentation process, and a real industrial data set of semiconductor etch process.
Notably, the fault detection and classification results demonstrated the effectiveness of
the proposed methods. |
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