Engine fault diagnosis utilizing adaptive morphological lifting wavelet and improved non-negative matrix factorization

被引：0

作者：

机构：

[1] Forth Department, Mechanical Engineering College, Shijiazhuang 050003, Hebei

[2] Military Representative Office in Shanghai

来源：

Li, B. (rommandy@163.com) | 1600年 / China Ordnance Industry Corporation卷 / 34期

关键词：

Adaptive morphological gradient lifting wavelet; Engine; Fault diagnosis; Improved non-negative matrix factorization; Information processing;

D O I：

10.3969/j.issn.1000-1093.2013.03.015

中图分类号：

学科分类号：

摘要：

Signal processing and feature extraction are two of the most significant steps for engine fault diagnosis. In order to overcome the limitations of the traditional wavelet and morphological wavelet, a new lifting scheme named adaptive morphological gradient lifting wavelet (AMGLW) is presented, which can select between two filters, the average filter and morphological gradient filter, to update the approximation signal based on the local gradient of the analyzed signal. Thus the impulsive components can be enhanced and the noise can be depressed simultaneously by the presented AMGLW scheme. Furthermore, the improved non-negative matrix factorization (INMF) is utilized to calculate the features for engine faults classification. The vibration signals acquired from an engine with five working states are employed to validate the proposed engine signal processing and feature extraction scheme.

引用

页码：353 / 360

页数：7

共 26 条

[1] Wu J.D., Chen J.C., Continuous wavelet transform technique for fault signal diagnosis of internal combustion engines, NDT and E International, 39, 4, pp. 304-311, (2006)
[2] Wang Z.-S., He H., Chen Q., Exploring effective early identification of aero-engine rotor faults, Journal of Northwestern Polytechnical University, 24, 1, pp. 68-71, (2006)
[3] Cao J.-J., Zhang P.-L., Zhang Y.-T., Et al., Feature extraction of an engine cylinder head vibration signal based on lifting wavelet package transformation, Journal of Vibration and Shock, 27, 2, pp. 34-38, (2008)
[4] Wu D.-H., Zhang P.-L., Ren G.-Q., Et al., Feature extraction of an engine vibration signal based on dual-tree wavelet package transformation, Journal of Vibration and Shock, 29, 4, pp. 160-165, (2010)
[5] Wu J.D., Liu C.H., Investigation of engine fault diagnosis using discrete wavelet transform and neural network, Expert Systems with Applications, 35, 3, pp. 1200-1213, (2008)
[6] Wu J.D., Liu C.H., An expert system for fault diagnosis in internal combustion engines using wavelet packet transform and neural network, Expert Systems with Applications, 36, 3 Part 1, pp. 4278-4286, (2009)
[7] Zhou R., Bao W., Li N., Et al., Mechanical equipment fault diagnosis based on redundant second generation wavelet packet transform, Digital Signal Processing: A Review Journal, 20, 1, pp. 276-288, (2010)
[8] Goutsias J., Heijmans H.J.A.M., Nonlinear multiresolution signal decomposition schemes-Part I: Morphological pyramids, IEEE Transactions on Image Processing, 9, 11, pp. 1862-1876, (2000)
[9] Heijmans H.J.A.M., Goutsias J., Nonlinear multiresolution signal decomposition schemes - Part II: Morphological wavelets, IEEE Transactions on Image Processing, 9, 11, pp. 1897-1913, (2000)
[10] Flouzat G., Amram O., Laporterie F., Et al., Multiresolution analysis and reconstruction by a morphological pyramid in the remote sensing of terrestrial surfaces, Signal Processing, 81, 10, pp. 2171-2185, (2001)

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