Abstract
Recently, cyclostationary blind deconvolution (CYCBD) is often used in gearbox fault feature extraction, and it is more effective in recovering single periodic pulse. However, in the engineering application of CYCBD, the filter length ( $L$ ) and cycle frequency ( $\alpha$ ) need to be verified and set through a large number of experiments, and the efficiency is very low; Moreover, the effect is not good when it is used to extract composite fault features under the background of strong noise. In order to overcome the above limitations, empirical mode decomposition (EEMD) is used to preprocess the composite fault. EEMD can remove the high-frequency noise and weak correlation components in the sampled signal. The strong correlation component is reconstructed to obtain the modal function closer to the fault frequency. The chimpanzee intelligent algorithm is applied to the determination of $L$ and $\alpha $ of CYCBD by optimization to form an adaptive CYCBD. Adaptive CYCBD takes the dispersion entropy of envelope spectrum as the fitness function of chimpanzee optimization algorithm (CHOA), and finds the optimal $L$ and $\alpha $ through iteration. The optimal parameter value is applied to CYCBD, and the reconstructed modal function is deconvoluted to obtain the optimal inverse filter, so as to accurately separate the fault characteristic components. Simulation and experimental results show that this method is effective for gearbox composite fault diagnosis and extraction under strong noise background.
Highlights
With the rapid development of modern industry, gearbox has been widely used, especially in the automotive transmission system
STEPS OF THE CHIMP OPTIMIZATION ALGORITHM The implementation steps of the chimp optimization algorithm to optimize cyclostationarity blind deconvolution (CYCBD) parameters are as follows: initialize the ChOA parameters and the chimpanzee population initialize the range of CYCBD optimization parameters L and α while(t < maximum number of iterations) for L and α: Select a random search agent end for calculate the dispersion entropy of the signal envelope spectrum after CYCBD noise reduction if ESDt (L α) ≤ ESDt+1(L α) update L and α else if return L and α t=t+1 end while return ESD and optimal parameters L and α of CYCBD
Taking the dispersion entropy of envelope spectrum as the objective function, the optimal cycle frequency and filter length corresponding to CMF1 and CMF2 are obtained by updating the optimization parameters
Summary
With the rapid development of modern industry, gearbox has been widely used, especially in the automotive transmission system. This paper forms an adaptive CYCBD method which takes the envelope spectral dispersion entropy as the fitness function of CHOA, and finds the optimal filter length and cycle frequency through iterative method.
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