Bearing Performance Degradation Assessment Based on Ensemble Empirical Mode Decomposition and Affinity Propagation Clustering

Xu, Fan; Song, Xiangbao; Tsui, Kwok‐Leung; Yang, Fangfang; Huang, Zhelin

doi:10.1109/access.2019.2913186

Cited by 28 publications

(16 citation statements)

References 34 publications

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“…Furthermore, it is observed in the proposed approach, that the cross channel leakage is lessened when the number of assisted noise channels and the noise power of assisted noise channel are increased, but it is proven that the power(variance) of the added noise should be (2‐10%) of the power of the input signal 35 . The idea of noise‐assisted thinking method depends on the investigation of the statistical properties of white noise 42‐45 . In addition, more assisted noise channel means more computational complexity; therefore, there is a trade‐off between the computational complexity and noise leakage.…”

Section: Verification Results and Discussionmentioning

confidence: 99%

Application of multivariate signal analysis in vibration‐based condition monitoring of wind turbine gearbox

Rafiq

Rashed

Shafik

2020

Int Trans Electr Energ Syst

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Summary The accuracy of fault diagnosis and condition monitoring of mechanical systems depends on the feature extraction of a non‐stationary vibration signals acquired from multiple accelerometer sensors. Extracting fault features of such complex vibration signals is a challengeable task due to the signals masked by an intensive noise. Recently, the multivariate empirical mode decomposition (MEMD) algorithm has been proposed in order to extend empirical mode decomposition (EMD) for the multi‐channel signal and make it suitable for processing multivariate signals. It is found that, likewise, EMD, MEMD is also essentially acting as a dyadic filter bank for the multivariate input signal on each channel. However, different from EMD, MEMD better aligns the same intrinsic mode functions (IMFs) across the same frequency range from different channels, which plays an important role in real‐world applications. However, MEMD still exhibits the degree of mode mixing problem, which affects the accuracy of extracting fault features. In this article, an improved MEMD, namely NAMEMD, is proposed to extract the most meaningful multivariate IMFs by adding uncorrelated white Gaussian noise in separate channels, under certain conditions, to enhance the decomposed multivariate IMFs by minimizing mode mixing problem. After that, a new method is proposed to select the most effective multivariate IMFs related to faults. To optimize the performance of extracting vibration fault features, a proposed noise‐assisted MEMD algorithm is then combined with a competent non‐linear Teager‐Kaiser energy operator, thereby guarantees a superior fault diagnosis performance. To verify the effectiveness of the proposed method, both a synthetic analytic signal and experimental wind turbine benchmark vibration datasets are utilized and tested. The results demonstrate that the proposed approach is suited for capturing a significant fault features in wind turbine multi‐stage gearboxes, thus providing a viable multivariate signal processing tool for wind turbine gearbox condition monitoring.

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Section: Verification Results and Discussionmentioning

confidence: 99%

Application of multivariate signal analysis in vibration‐based condition monitoring of wind turbine gearbox

Rafiq

Rashed

Shafik

2020

Int Trans Electr Energ Syst

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“…The AP clustering algorithm proposed by Frey and Dueck is based on neighbor information propagation [32]. Unlike fuzzy c-means, which computes the mean value of the data points to obtain the centers of the clusters, AP clustering considers all samples as candidates for the cluster center points [33], [34]. And compared with other popular clustering methods, such as k-means [35] and k-medoids [36], [37], which require manual selection of cluster number in advance, the AP clustering automatically locates all the available cluster centers.…”

Section: E Tht Theoretical Process Of Ap Clustering Analysismentioning

confidence: 99%

Study of Color Rendering Evaluation Method of Light Sources for Printing Matter

Lian

Liu

et al. 2020

IEEE Access

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Based on the optimization of color samples, we have developed a method to evaluate light sources' color rendering of printing matter. By performing Affinity Propagation (AP) Clustering Algorithm on the color appearance and spectra of the color printing atlas samples printed by a press, two typical color sample sets are obtained. The optimized color sample (OCS) set consists of these two typical color sample sets and it is presented by CMYK dot area coverage. The color rendering indexes (CRIs) CIE-R a , CRI2012, CIE-R f of 90 light sources are calculated by taking the OCS set, color printing atlas and standard color sample (SCS) set of CRI as the test color sample (TCS) set. By comparing the Absolute Difference (AD), Mean Absolute Difference (MAD), Coefficient of Variation (CV) and Spearman Correlation Coefficient (SCC) of the CRIs, we find that the indexes calculated by OCS set are closer to these indexes calculated by color printing atlas than by SCS set. Therefore, the OCS set is more suitable for printing applications. After output from a press and measured spectra, the OCS set with CMYK dot area coverage can be used as the TCS set to evaluate the color rendering of light sources for all printing matter output from this press. For proving the reliability of the results, that is, the universality of the OCS set to the presses, the OCS set with fixed CMYK dot area coverage is output from an another press and CRIs are calculated. The results show that OCS set we developed is better than the SCS set. This method can be used for color rendering evaluation of light sources for printing matter.

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“…In addition, EMD lacks a strict mathematical theory foundation and has poor noise resistance. Wu et al proposed EEMD [ 20 , 21 ] based on a noise-assisted approach. The principle is to add appropriate white noise to make it continuous on the time scale, which can better separate the inherent scale of the signal.…”

Section: Introductionmentioning

confidence: 99%

A Rolling Bearing Fault Classification Scheme Based on k-Optimized Adaptive Local Iterative Filtering and Improved Multiscale Permutation Entropy

Zhang

2021

Entropy

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The health condition of the rolling bearing seriously affects the operation of the whole mechanical system. When the rolling bearing parts fail, the time series collected in the field generally shows strong nonlinearity and non-stationarity. To obtain the faulty characteristics of mechanical equipment accurately, a rolling bearing fault detection technique based on k-optimized adaptive local iterative filtering (ALIF), improved multiscale permutation entropy (improved MPE), and BP neural network was proposed. In the ALIF algorithm, a k-optimized ALIF method based on permutation entropy (PE) is presented to select the number of ALIF decomposition layers adaptively. The completely average coarse-graining method was proposed to excavate more hidden information. The performance analysis of the simulation signal shows that the improved MPE can more accurately dig out the depth information of the time series, and the entropy value obtained is more consistent and stable. In the research application, rolling bearing time series are decomposed by k-optimized ALIF to obtain a certain number of intrinsic mode functions (IMFs). Then the improved MPE value of effective IMF is calculated and input into backpropagation (BP) neural network as the feature vector for automatic fault identification. The comparative analysis of simulation signals shows that this method can extract fault information effectively. At the same time, the experimental part shows that this scheme not only effectively extracts the fault features, but also realizes the classification and identification of different fault modes and faults of different degrees, which has a certain application prospect in the research and application direction of rolling bearing fault identification.

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Bearing Performance Degradation Assessment Based on Ensemble Empirical Mode Decomposition and Affinity Propagation Clustering

Cited by 28 publications

References 34 publications

Application of multivariate signal analysis in vibration‐based condition monitoring of wind turbine gearbox

Application of multivariate signal analysis in vibration‐based condition monitoring of wind turbine gearbox

Study of Color Rendering Evaluation Method of Light Sources for Printing Matter

A Rolling Bearing Fault Classification Scheme Based on k-Optimized Adaptive Local Iterative Filtering and Improved Multiscale Permutation Entropy

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