Litcius/Paper detail

Improved 2-D Multiscale Fractional Dispersion Entropy: A Novel Health Condition Indicator for Fault Diagnosis of Rolling Bearings

Hao Song, Rui Yuan, Yong Lv, Haiyang Pan, Xingkai Yang

2023IEEE Sensors Journal12 citationsDOI

Abstract

The multiscale dispersion entropy (MDE), which measures the irregularity or chaos of 1-D univariate time series through a dispersion pattern, is a useful tool to extract features from bearing signals. However, the stable dynamical characteristics of bearing signals are commonly hidden in high-dimensional state spaces, which cannot be easily captured by MDE. A large number of fractional chaotic information is filtered due to the application of integer-order pattern probability, negatively impacting the characterization performance of MDE on nonlinear signals. Therefore, an improved 2-D multiscale fractional dispersion entropy (IMFDE2-D) is proposed to overcome the shortcomings of MDE. In IMFDE2-D, the proper state space is constructed to reveal the high-dimensional dynamic characteristics of bearing signals. Meanwhile, the 2-D fractional dispersion pattern is developed to scan the space structure and supplement the fractional chaotic information. Furthermore, the first point of 2-D coarse-graining process is diagonally moved to alleviate the space compression, which further improves the stabilities of entropy metrics. The Logistic and Hénon maps demonstrate that IMFDE2-D has a better capability to describe the states of complex systems compared with MDE. To establish the intelligent health condition identification scheme, a novel feature selection algorithm called iterative Davies–Bouldin index (iDBI) is further designed to refine entropy features. The experimental results demonstrate that under the condition of supervised learning, IMFDE2-D–iDBI achieves the average accuracies of 100% and 99.91%, respectively, in various bearing experiments. Furthermore, even with an unsupervised classifier, the average accuracies can still reach 95.57% and 100%, which are much higher than those of traditional indicators.

Topics & Concepts

Dispersion (optics)Condition monitoringFault (geology)Entropy (arrow of time)Statistical physicsPhysicsComputer scienceMaterials scienceEngineeringElectrical engineeringThermodynamicsGeologyOpticsSeismologyAdvanced machining processes and optimizationMachine Fault Diagnosis TechniquesMetallurgy and Material Forming