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1. Introduction

Stochastic resonance (SR) is a kind of nonlinear phenomena where noise is injected into nonlinear systems to enhance their outputs [1]. Therefore, SR lets us discover the benefits of noise [2]. With the development of research, it is found that there are lots of the benefits of noise in real world in addition to SR [3], for example chaotic resonance [4–6] and vibrational resonance [7]. Such a behavior has attracted sustaining attention to apply it into various fields such as image enhancement [8], information transmission [9], and fault detection and fault diagnosis of rotating machinery [10–13], especially the development and future directions of SR in machine fault diagnosis have been summarized and proposed by [10, 14].

Among them, SR-based fault detection and fault diagnosis has become one of the most widely studied and applied directions. They can be categorized into novel potentials [15], novel nonlinear systems [16], novel behaviors [17], novel methodologies [18], and others. Because this paper focuses on improving novel nonlinear systems, we would review the development of novel nonlinear systems, which mainly contains two aspects.

On the one hand, some scholars attempt to add the fractional-order derivative into nonlinear systems to induce more abundant dynamics for better weak signal detection than those without fractional-order derivative. For example, Zheng et al. applied genetic algorithms to optimize the multi parameters of fractional-order SR for weak signal detection [19]. Yang et al. investigated stochastic P-bifurcation and SR in fractional-order bistable nonlinear systems, indicating that the fractional-order SR can enhance the weak signal better than integral-order ones [20]. Zeng et al. designed a new indicator, namely, weighted correctional signal-to-noise ratio, to tune the parameters of fractional-order SR for mechanical fault diagnosis [21]. Qiao et al. employed the fractional-order derivative to improve the second-order SR for enhancing weak fault signature of machinery [22]. Guo et al. studied the effect of random mass and signal-modulated noise on SR in fractional-order harmonic oscillators [23]. Yu et al. explored the SR in two coupled fractional harmonic oscillators induced by a dichotomous fluctuating mass, indicating that coupling strength and the fractional order both benefit to weak signal detection [24]. Zhong et al. studied the collective SR in globally coupled fractional-order harmonic oscillators induced by multiplicative noise [25]. The above researches indicated that the fractional-order derivative is able to improve SR for weak signal detection than integral-order ones.

On the other hand, time delay can utilize the historical information of nonlinear systems to enhance weak signal detection, whereas feedback could achieve the precise control of nonlinear systems for improving the output. Therefore, some scholars pay more attention to studying the SR with time delay and feedback. For example, Wu and Zhu investigated the SR in a bistable system with time-delayed feedback driven by non-Gaussian noise by using two indicators including quasi-steady-state probability distribution function and signal-to-noise ratio (SNR) [26]. Lu et al. proposed a time-delayed feedback SR method for mechanical fault diagnosis [27]. Shi et al. presented a time-delayed tristable SR method for mechanical fault diagnosis, suggesting that time delay and feedback affect the noise enhanced stability [28]. Meanwhile, Shi et al. designed a high-order time-delayed feedback tristable SR method for enhancing weak fault signature [29]. Wadop Ngouongo et al. reported the SR with memory effects in a deformation potential [30]. Wang et al. studied the effect of fractional damping and time-delayed feedback on SR [31]. Li et al. studied the time-delayed feedback monostable SR in bearing fault diagnosis by fusing minimum entropy deconvolution [32]. Wang et al. explored the influences of time-delayed feedback on logical SR and the results indicated that the delay time can enhance the output SNR [33]. Yang et al. indicated that the time delay can control primary resonance and SR, and increasing feedback intensity can suppress the vibrations [34]. Liu et al. proposed a controlled SR method with time-delayed feedback to enhance weak fault signature of machinery [35]. In sum, both time delay and feedback can improve the weak signal detection of SR by precise control and information memory.

The above summary of literature has indicated that both fractional-order derivative and time-delayed feedback can improve the weak signal detection of SR from historical information memory, precise control, and so on. Up to now, however, the SR with both fractional-order derivative and time-delayed feedback has not been studied and applied to mechanical fault diagnosis yet. Therefore, this paper attempts to fuse their advantages to improve the weak signal detection of SR further, thereby enhancing the weak early fault signature of the machinery. Inspired by such an idea, the remainder of this paper is organized as follows. Section 2 designs a SR model enhanced by fractional-order derivative and time-delay feedback and provides its mathematical expression. In Section 3, we apply the SR enhanced by fractional-order derivative and time-delay feedback to bearing fault diagnosis and a bearing fault experiment is performed to demonstrate its effectiveness and feasibility. Even the comparison between those with or without fractional-order derivative and time-delay feedback is made. Finally, conclusions are drawn in Section 4.

2. An SR Model Enhanced by Fractional-Order Derivative and Time-Delay Feedback

The existing nonlinear systems of SR are of two kinds: overdamped and underdamped ones [36]. Overdamped SR characterizes the low-pass filtering properties [37, 38], while underdamped SR characterizes the band-pass filtering properties which is more suitable to enhance weak signals under strong background noise than overdamped ones [39, 40]. Hence, we pay attention to underdamped SR and it can be described as follows:$$\begin{array}{}\text{(1)}& \frac{{\mathrm{d}}^{2}x}{\mathrm{d}{t}^2}+\gamma \frac{\mathrm{d}x}{\mathrm{d}t}=-\frac{\partial Ux}{\partial x}+A\cos {\omega }_{0}t+\epsilon t,\end{array}$$where $\gamma$ is the damping factor and $\gamma >0$, $A$ and ${\omega }_0$ are the amplitude and angular frequency of the periodic signal. $x$ and $t$ are moving trajectory of Brownian particles in $Ux$ as time varies and time, respectively. $\epsilon t$ is the Gaussian white noise. $Ux$ is the harmonic-Gaussian double-well potential given by equation (2) and has richer dynamics than classical bistable potential. Therefore, it can be used to design the SR model enhanced by fractional-order derivative and time-delay feedback.$$\begin{array}{}\text{(2)}& Ux=\frac{k}{2}{x}^2+\alpha \exp -\beta x^2,\end{array}$$where $k$, $\alpha$, and $\beta$ are the adjusting parameters. The harmonic-Gaussian double-well potential has two stable states and one unstable state located at $x_{\pm }=\pm \sqrt{\ln 2\alpha \beta /k/\beta }$ and $x_u=0$, respectively. The height of potential barrier is $∆U=\alpha -k1+\ln 2\alpha \beta /k/2\beta$. To keep the bistability of harmonic-Gaussian double-well potential, $2\alpha \beta /k>0$ and further $k<2\alpha \beta$. The potential is plotted in Figure 1 under different tuning parameters. It can be found that when $\alpha$ and $\beta$ are kept unchanged, tuning $k$ can change the depth and width of double wells, as shown in Figure 1(a), where $k<2\alpha \beta$. When $k$ starts to become larger and $k>2\alpha \beta$, the bistability of harmonic-Gaussian double-well potential loses becomes a monostable potential, as shown in Figure 1(b). Therefore, the following work would be performed under the condition of $k>2\alpha \beta$.

[figure(s) omitted; refer to PDF]

Furthermore, the Grunwald–Letnikov fractional-order derivative [41, 42] is added into equation (1) as follows:$$\begin{array}{}\text{(3)}& \frac{{\mathrm{d}}^{2}x}{\mathrm{d}{t}^2}+\gamma \frac{{\mathrm{d}}^{\vartheta }x}{\mathrm{d}{t}^{\mathrm{\vartheta }}}=-\frac{\partial Ux}{\partial x}+A\cos {\omega }_{0}t+\epsilon t,\end{array}$$where $\vartheta$ is the fractional order and $\vartheta \in 0,2$ [43]. We rewrite equation (3) for numerical solution easily as follows:$$\begin{array}{}\text{(4)}& \begin{array}{c}\frac{{\mathrm{d}}^{\vartheta }x}{\mathrm{d}{t}^{\mathrm{\vartheta }}}=y,\\ \frac{{\mathrm{d}}^{2}x}{\mathrm{d}{t}^2}=\frac{{\mathrm{d}}^{\phi }y}{\mathrm{d}{t}^{\phi }},\phi =2-\vartheta ,\\ \frac{{\mathrm{d}}^{\phi }y}{\mathrm{d}{t}^{\phi }}=-\gamma y-\frac{\partial Ux}{\partial x}+A\cos {\omega }_{0}t+\epsilon t.\end{array}\end{array}$$

According to the definition of the Grunwald–Letnikov fractional-order derivative, equation (4) can be transformed into the following discrete expression:$$\begin{array}{}\text{(5)}& \begin{array}{c}xl=-{\displaystyle \sum }_{j=1}^{l-1}{\omega }_j^{\vartheta }xl-j+h^{\vartheta }yl-1,\\ yl=-{\displaystyle \sum }_{j=1}^{l-1}{\omega }_j^{\phi }yl-j+h^{\phi }-\gamma yl-1-kxl-1+2\alpha \beta xl-1\exp -\beta x^{2}l-1+Fl-1,\end{array}\end{array}$$where ${\omega }_0^{\vartheta }=1$, ${\omega }_l^{\vartheta }=1-\vartheta +1/l{\omega }_{l-1}^{\vartheta }$, and $l=1,2,...,N$ in which $N$ is the length or the number of sampling points of the signal $Ft=A\cos {\omega }_{0}t+\epsilon t$. The variable $h$ is the integral step. $xl,yl,\text{and\hspace{0.17em}}Fl$ are the corresponding discrete expressions of $xt,yt,\text{and\hspace{0.17em}}Ft$, respectively. It can be seen from equation (5) that adding the fractional-order derivative into the underdamped SR can make the current value of output $xt$ highly depend on historical values of the past. Due to the above reason, the fractional-order derivative can enhance the weak signal detection of SR. Moreover, such a property is consistent with a mechanical signal which has high dependence between each value.

Furthermore, we consider the memory of time delay to historical information and the precise control of feedback to the output of SR [44]. The time-delay feedback item is added into equation (4) to obtain the following equation:$$\begin{array}{}\text{(6)}& \begin{array}{c}\frac{{\mathrm{d}}^{\vartheta }xt}{\mathrm{d}{t}^{\mathrm{\vartheta }}}=yt,\\ \frac{{\mathrm{d}}^{2}xt}{\mathrm{d}{t}^2}=\frac{{\mathrm{d}}^{\phi }yt}{\mathrm{d}{t}^{\phi }},\phi =2-\vartheta ,\\ \frac{{\mathrm{d}}^{\phi }yt}{\mathrm{d}{t}^{\phi }}=-\gamma yt-kxt+2\alpha \beta xt\exp -\beta {xt}^2+\theta xt-\tau +Ft,\end{array}\end{array}$$where $\theta >0$ is the feedback strength and $\tau$ is the time delay. Equation (6) can be discretized to solve it numerically as follows:$$\begin{array}{}\text{(7)}& \begin{array}{c}xl=-{\displaystyle \sum }_{j=1}^{l-1}{\omega }_j^{\vartheta }xl-j+h^{\vartheta }yl-1,\\ \begin{array}{c}yl=-{\displaystyle \sum }_{j=1}^{l-1}{\omega }_j^{\phi }yl-j,\\ +h^{\phi }-\gamma yl-1-kxl-1+2\alpha \beta xl-1\exp -\beta x^{2}l-1+\theta xl-\tau f_s+Fl-1,\end{array}\end{array}\end{array}$$where $f_s$ is the sampling frequency and the notation $\bullet$ stands for round down. In equation (7), when $-\tau /h<0$, $xl-\tau f_s=x0=0$. According to the conclusions in [45, 46], the small delay is acceptable when $\tau <1$.

Therefore, a SR model enhanced by fractional-order derivative and time-delay feedback is built in equation (6) and its numerical solution expression can be given by equation (7). In the model, there are eight tuning parameters to control the SR for enhancing weak signal detection, including fractional order $\vartheta \in 0,2$, damping factor $\gamma >0$, harmonic-Gaussian double-well potential parameters including $k$, $\alpha$, and $\beta$ with the condition $k<2\alpha \beta$, feedback strength $\theta$, time delay $0<\tau <1$, and integral step 0 < $h$ < 1. Obviously, it is impossible for us to set up these tuning parameters artificially. For this purpose, we would use the optimization algorithms to tune these parameters automatically in this proposed method for enhancing weak fault signature of machinery.

3. Fractional-Order Derivative and Time-Delay Feedback Enabled Stochastic Resonance for Bearing Fault Diagnosis

In this section, we would propose an adaptive SR method based on the model built in Section 2 to enhance weak fault signature for identification. Moreover, an experiment on bearing faults was performed to verify the feasibility and effectiveness of the proposed method.

3.1. The Proposed Method

The proposed fractional-order derivative and time-delay feedback enabled stochastic resonance method for bearing fault diagnosis is shown in Figure 2 and the detailed processes are given as follows:

(1) Parameter initialization: The proposed method is based on the SR model built in equation (6) and, therefore, it has eight tuning parameters including fractional order $\vartheta$, damping factor $\gamma$, potential parameters $k$, $\alpha$ and $\beta$, feedback strength $\theta$, time delay $\tau$, and integral step $h$. According to their definitions and physical meanings, they are initialized as $\vartheta \in 0,2$, $\gamma \in 0,+\infty$, $k\in 0,+\infty$, $\alpha \in 0,+\infty$, $\beta \in 0,+\infty$, $\theta \in 0,+\infty$, $\tau \in 0,1$, and $h\in 0,1$, respectively.

[figure(s) omitted; refer to PDF]

3.2. Experimental Verification

In this subsection, the proposed fractional-order derivative and time-delay feedback enabled stochastic resonance method is applied to bearing fault diagnosis for verifying its feasibility and effectiveness. Due to contact fatigue, uneven lubrication, misalignment, and so on, it is inevitable for roller bearings to occur wears and other types of defects [47–49]. In early stage of defects, the changes of vibration and oil temperature of bearings are too weak to be visible to the naked eye [50]. In serious stage of defects, the changes of vibration and oil temperature of bearings are very clear to be observed by ears and fingers [51]. Therefore, it is a challenge for us to detect the early defects of bearings by using advanced methods and technologies. For this purpose, we would apply the proposed method to early fault diagnosis of bearings.

Four Rexnord ZA-2115 double row bearing run-to-failure experiments under the rotating speed 2000 rpm and radial load 6000 lbs were performed to acquire the bearing failure data by using PCB 353B33 accelerometers and a data acquisition card. The bearing experimental rig is shown in Figure 3(a) and the corresponding sensor placement is illustrated in Figure 3(b). This experimental rig is composed of four tested bearings, an AC motor, and rub belts. In the bearing run-to-failure experiment, the sampling frequency is 20 kHz and the sampling time is 1.024 seconds. The experimental parameters of tested bearing are shown in Table 1. In the process of experiment, an inner race defect occurs on the tested bearing 3, as shown in Figure 3(c). According to the equation that $f_{\text{inner}}=r_{\text{speed}}/60\ast 1/2\ast n1+d/D\cos \psi$, where $f_{\text{inner}}$ is inner race fault characteristic frequency, $r_{\text{speed}}$ is the rotating speed, $n$ is the number of rollers, $d$ is the roller diameter, $D$ is the pitch diameter, and $\psi$ is the contact angle, and the theoretical inner race fault characteristic frequency $f_{\text{inner}}=296.93\text{Hz}$.

[figure(s) omitted; refer to PDF]

Table 1

Experimental parameters of tested bearings.

The time-domain signal collected from a bearing usually changes when a damage occurs in a bearing. Both its amplitude and distribution may be different from those of the time-domain signal of a normal bearing. Root mean square (RMS) reflects the vibration amplitude and energy in time domain [53]. Figure 4(a) depicts the RMS of the tested bearing 3. It can be found from Figure 4(a) that the RMS starts to be stable and then becomes larger slowly and finally degenerates rapidly. To the end, a serious defect occurred on the tested bearing 3. Therefore, we choose the vibration signal at the early stage of defects to perform the spectral analysis, as shown in Figure 4(b). From the raw signal, we can see weak impacts but they are submerged by strong noise. In Figure 4(c), there are clear spectrum peaks at 232.5 Hz, 493.8 Hz, etc., but we cannot see the spectral peaks at the inner race fault characteristic frequency and its harmonics. Meanwhile, we also cannot see the corresponding spectral peaks from the zoomed envelope spectrum in Figure 4(d).

[figure(s) omitted; refer to PDF]

The raw signal in Figure 4(b) is fed into the proposed method and the underdamped SR without both fractional derivative and time-delay feedback to enhance weak fault signature, respectively. The enhanced results are plotted in Figure 5. It can be found that there are clear repetitive impacts in the time-domain signal as shown in Figure 5(a) and we can see the eye-catching spectral peaks at the inner race fault characteristic frequency and its harmonics from the corresponding frequency spectrum in Figure 5(b) and even side frequency bands with the interval rotating frequency. The above information tells us the fact that an inner race wear has happened in the tested bearing 3. The diagnosis results are consistent with the experimental results. Meanwhile, Figures 5(c) and 5(d) show the enhanced signal and its zoomed frequency spectrum by using the underdamped SR without both fractional derivative and time-delay feedback, where the objective function is usually SNR instead of LSNR. It can be noticed that there exists a eye-catching spectral peak at the inner race fault characteristic frequency, but we cannot see other any diagnostic information, that is, because the SNR indicator would be calculated by the ratio between the energy at the inner race fault characteristic frequency and the energy at the whole frequency band in addition to fault signature, resulting in energy concentration and ignoring other diagnostic information. Moreover, the spectral peak at the inner race fault characteristic frequency using the proposed method is higher than that one using underdamped SR without both fractional derivative and time-delay feedback. The above comparison demonstrates that the proposed method has richer diagnostic information and higher spectral peak at the inner race fault characteristic frequency than underdamped SR without both fractional derivative and time-delay feedback.

[figure(s) omitted; refer to PDF]

For comparison, the advanced infogram method [54–56] is applied to process the raw vibration signal in Figure 4(b), and the infogram for selecting the most informative frequency band is shown in Figure 6. It can be seen that the SE infogram in Figure 6(a) and SES infogram in Figure 6(b) select different filtered frequency band and its parameters. Therefore, we apply two filtered frequency bands to filter the raw signal and the results are depicted in Figure 7. It can be seen that the SE infogram filters out the cyclostationary information as shown in Figure 7(a), but we cannot see the peaks at the inner race fault characteristic frequency and its harmonics from Figure 7(b). On the contrary, the SES infogram filters out the impulsivity information as shown in Figure 7(c), but we cannot also see the peaks at the inner race fault characteristic frequency and its harmonics from Figure 7(d). The comparison with other non-SR methods demonstrates the feasibility and superiority of the proposed method further.

[figure(s) omitted; refer to PDF]

4. Conclusions

Stochastic resonance (SR) has become a hot signal processing method and has been widely used in mechanical fault diagnosis, such as fractional-order SR and time-delayed feedback SR. Here, fractional-order SR can utilize the historical information to enhance weak fault signature, and time delay and feedback can improve the memory of SR and tune it precisely. Therefore, we attempt to fuse fractional-order derivative and time-delayed feedback to develop the better SR method. Inspired by the idea, fractional-order derivative and time-delay feedback enabled SR method for bearing fault diagnosis is proposed in this paper. The comparison with the advanced infogram and the SR without fractional-order derivative and time-delay feedback is made. The results indicate that the proposed method has a little superiority in enhancing weak fault signature and richer diagnostic information in the enhanced results than the SR without fractional-order derivative and time-delay feedback. In future work, we would pay more attention to design SR-based filters to take the place of filters in infogram for exploring the SR-based infogram.

Authors’ Contributions

Yidan Mei conducted the experimental work, performed data analysis, provided theoretical explanations, and drafted the manuscript. Lutie Chen and Wentao Xu provided valuable feedback and constructive suggestions. Chao Liu and Zijian Qiao conducted a thorough review and made substantial revisions to the technical paper. Zhihui Lai contributed to the linguistic accuracy and fluency of the academic manuscript.

Acknowledgments

This research was supported by the Zhejiang Provincial Natural Science Foundation of China (LQ22E050003), Ningbo Natural Science Foundation (2022J132), National Natural Science Foundation of China (52205569), Chuying Planning Project of Zhejiang Provincial Administration for Market Regulation (CY2023328), Ningbo Science and Technology Major Project (2023Z133), and Laboratory of Yangjiang Offshore Wind Power (YJOFWD-OF-2022A08), and also sponsored by K.C. Wong Magna Fund in Ningbo University.