Abstract
The fault classification of a small sample of high dimension is challenging, especially for a nonlinear and non-Gaussian manufacturing process. In this paper, a similarity-based feature selection and sub-space neighbor vote method is proposed to solve this problem. To capture the dynamics, nonlinearity, and non-Gaussianity in the irregular time series data, high order spectral features, and fractal dimension features are extracted, selected, and stacked in a regular matrix. To address the problem of a small sample, all labeled fault data are used for similarity decisions for a specific fault type. The distances between the new data and all fault types are calculated in their feature subspaces. The new data are classified to the nearest fault type by majority probability voting of the distances. Meanwhile, the selected features, from respective measured variables, indicate the cause of the fault. The proposed method is evaluated on a publicly available benchmark of a real semiconductor etching dataset. It is demonstrated that by using the high order spectral features and fractal dimensionality features, the proposed method can achieve more than 84% fault recognition accuracy. The resulting feature subspace can be used to match any new fault data to the fingerprint feature subspace of each fault type, and hence can pinpoint the root cause of a fault in a manufacturing process.
Highlights
The emerging industry 4.0 is based on smart sensors that monitor a complex manufacturing process and machine intelligence techniques that automate the process control by extracting knowledge from the sensing data
I query where mi is the index of data in the ith fault type, Mi is the number of fault data of fault type i, Xi is m the query data vector in the feature subspace of fault type i, and Xi i the mth classified data vector in i the data set of fault type i measured in the feature subspace of fault type i
The remaining classified fault data are used for searching the feature subspace of each type of fault dataset by the Equations (7)–(9)
Summary
The emerging industry 4.0 is based on smart sensors that monitor a complex manufacturing process and machine intelligence techniques that automate the process control by extracting knowledge from the sensing data. A fault classification method will classify the faulty data into specific types for further identification of fault causes and correction. Many intelligent data-driven classification techniques have been proposed for fault detection of manufacturing processes given multidimensional time-series sensing data, including Principal. Du [2] demonstrated that high order spectral (HOS) features and further PCA extraction can significantly improve the fault detection accuracy and lower the false alarm rate of one-class classifiers for nonlinear and non-Gaussian sensing data. To classify small and high dimensional fault data of nonlinearity and non-Gaussianity, the following innovative methods are proposed:. To address a small fault sample size, all labeled data of a specific fault are used in its feature subspace, as the similarity neighborhood of the fault, to measure the closeness of new fault data to this fault.
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