Weak Fault Detection for Rolling Bearings in Varying Working Conditions through the Second‐Order Stochastic Resonance Method with Barrier Height Optimization

Shi, Huaitao; Li, Yangyang; Zhou, Peng; Tong, Shenghao; Guo, Liang; Li, Baicheng

doi:10.1155/2021/5539912

Cited by 3 publications

(1 citation statement)

References 32 publications

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“…However, due to the large number of experimental samples required, such methods are not suitable for all fault diagnostic purposes. The third is to use noise energy to enhance the signal energy to be tested-an example of this approach is the stochastic resonance (SR) method [9,10]. SR has the advantage that it can superimpose part of the noise energy on the signal and achieve enhanced detection of weak signals when the input and output signals of the system are synchronized [11].…”

Section: Introductionmentioning

confidence: 99%

Bearing Fault Diagnosis Based on Stochastic Resonance and Improved Whale Optimization Algorithm

et al. 2022

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In light of the problem of difficult model parameter selection and poor resonance effects in traditional bearing fault detection, this paper proposes a parameter-adaptive stochastic resonance algorithm based on an improved whale optimization algorithm (IWOA), which can effectively detect bearing fault signals of rotating machinery. First, the traditional WOA was improved with respect to initial solution distribution, global search ability and population diversity generalization, effectively improving the global convergence of the WOA. Then, the parameters of the bistable stochastic resonance model were optimized using the improved WOA, and adaptive adjustment of the stochastic resonance parameters was realized. Finally, the Case Western Reserve University bearing data set and the XJTU-SY bearing data set were used as fault data for the actual bearing to be tested for experimental verification. The signal-to-noise ratios of the detected fault frequencies for the above two data sets were −20.5727 and −21.1289, respectively. Among the algorithms compared, the IWOA proposed in this paper had the highest signal-to-noise ratio of the detected fault frequencies. The experimental results show that the proposed method can effectively detect a weak bearing fault signal in enhanced noise.

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Section: Introductionmentioning

confidence: 99%

Bearing Fault Diagnosis Based on Stochastic Resonance and Improved Whale Optimization Algorithm

et al. 2022

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Bearing fault signal detection based on whale algorithm to optimize stochastic resonance parameters

Huang

Zhang

2022

2022 34th Chinese Control and Decision Conference (CCDC)

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Adaptive Enhancement for Coal-Rock Cutting Sound Based on Parameter Self-Tuning Bistable Stochastic Resonance Model

Jie

Ren

Liu

et al. 2022

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The traditional bistable stochastic resonance model has always had the drawback of being difficult when choosing accurate system parameters when a weak signal is enhanced. This paper proposes a parameter self-tuning adaptive optimization method based on the bat optimization algorithm to address this issue. The cubic mapping strategy of chaos optimization is introduced in the initial process of the individual position of the bat algorithm. Chaos is characterized by randomness, sensitivity, fractal dimension, and universality. The initial problem of the algorithm falling into local extremums is overcome. The global search capability of the basic bat optimization algorithm has been improved. The improved bat optimization algorithm’s objective function is the signal-to-noise ratio (SNR) of the target weak signal output by the bistable stochastic resonance model. An adaptive signal enhancement algorithm based on the improved bat optimization algorithm and bistable stochastic resonance (IBA-BSR) model is constructed to increase the proportion of weak signals in the mixed signal. Simulation signals are created to validate the proposed algorithm’s feasibility. The engineering application effect of this algorithm is further demonstrated by enhancing the sound signal of coal and rock cutting by a shearer in a coal face. Engineering test results demonstrate that this algorithm can significantly increase the SNR of coal and rock cutting sound signals by 42.4537 dB, and the effect is remarkable.

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Weak Fault Detection for Rolling Bearings in Varying Working Conditions through the Second‐Order Stochastic Resonance Method with Barrier Height Optimization

Cited by 3 publications

References 32 publications

Bearing Fault Diagnosis Based on Stochastic Resonance and Improved Whale Optimization Algorithm

Bearing Fault Diagnosis Based on Stochastic Resonance and Improved Whale Optimization Algorithm

Bearing fault signal detection based on whale algorithm to optimize stochastic resonance parameters

Adaptive Enhancement for Coal-Rock Cutting Sound Based on Parameter Self-Tuning Bistable Stochastic Resonance Model

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