کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
560091 | 1451852 | 2016 | 15 صفحه PDF | دانلود رایگان |
• A set of differential geometry-based methods for bearing diagnostics is presented.
• A modified Local Projection method is proposed for noise reduction.
• The manifold features are extracted using Hessian locally linear embedding and SVD.
• Information geometry-based support vector machine is applied for fault diagnosis.
• Manifold distance and Gaussian mixture model are combined for health assessment.
The structures around bearings are complex, and the working environment is variable. These conditions cause the collected vibration signals to become nonlinear, non-stationary, and chaotic characteristics that make noise reduction, feature extraction, fault diagnosis, and health assessment significantly challenging. Thus, a set of differential geometry-based methods with superiorities in nonlinear analysis is presented in this study. For noise reduction, the Local Projection method is modified by both selecting the neighborhood radius based on empirical mode decomposition and determining noise subspace constrained by neighborhood distribution information. For feature extraction, Hessian locally linear embedding is introduced to acquire manifold features from the manifold topological structures, and singular values of eigenmatrices as well as several specific frequency amplitudes in spectrograms are extracted subsequently to reduce the complexity of the manifold features. For fault diagnosis, information geometry-based support vector machine is applied to classify the fault states. For health assessment, the manifold distance is employed to represent the health information; the Gaussian mixture model is utilized to calculate the confidence values, which directly reflect the health status. Case studies on Lorenz signals and vibration datasets of bearings demonstrate the effectiveness of the proposed methods.
Figure optionsDownload as PowerPoint slide
Journal: Mechanical Systems and Signal Processing - Volume 80, 1 December 2016, Pages 377–391