Condition monitoring of electric motors is an important field of study. There are many techniques to detect failures in electric motors. The classical one is vibration analysis; however, it allows for the detection of mostly mechanical problems in electric motors. Thus, other sources of information have also been investigated (current, speed, torque, sound, temperature, including infrared thermography, image; see more in several review papers ()). As rolling element bearing failures are the most common mechanical reason for electric motor breakdown (), accounting for nearly 40 % of all failure causes, this paper focuses on vibration analysis for bearing fault detection. The most popular method for bearing fault detection is envelope analysis (). However, it often requires some preprocessing, i.e., prefiltering, to extract the signal with a monocomponent carrier before demodulation. Another reason for pre-filtering is related to signal-to-noise ratio improvement. There are many works related to the selection of informative frequency bands; one of the most popular is spectral kurtosis (). Many possible statistics could be used for band selection (), a recent review of existing methods can be found in . It is also recommended to study the work of , where the authors considered a method for localized bearing fault detection based on the application of spectral kurtosis and envelope analysis applied to the stator current.

In this section, basic definitions of cyclic spectral coherence is presented, while some indicators used for comparing approaches will be recalled in the Appendix B.

Cyclic spectral coherence (CSC) is a well-known bi-frequency representation often used to investigate the cyclostationary aspects of time series {Xt}. It is defined as a double Fourier transform calculated on the instantaneous autocovariance function, such as : 1CX(f,ϵ)=SX(f,ϵ)SX(f+ϵ/2,0)SX(f-ϵ/2,0), where 2SX(f,ϵ)=lim⁡N→∞1N∑t=-NN∑τ=-∞∞RX(t,τ)e-i2πfτe-i2πϵt, where ϵ is the cycle frequency and RX(t,τ)=EXtXt-τ is the autocovariance function of time series {Xt}. In this application, f can be understood as the carrier frequency and ϵ as the modulating frequency, both expressed in Hz. SX(f,ϵ) is estimated using averaged cyclic periodogram (ACP) ().

It is important to remember that in practical implementation, the estimator of the CSC is calculated for time series x={x1,x2,…,xN} of length N. There are many approaches for estimating CSC, but the most popular method (also used in this article) is based on the averaged cyclic periodogram. It results in the calculation of the bi-frequency map C^X(f,ϵ), where f∈F and ϵ∈E.

If one can assume that the model of the investigated signal x displays cyclostationary properties, then one could observe the modulation fringes (individual vertical lines visible on the CSC map) located at specific modulating frequencies ϵl={ϵl1,ϵl2,…,ϵlP} representing the fundamental frequency of modulation (called fault frequency) and its harmonic multiples. Those fringes typically occupy a limited carrier frequency band ff∈F called the informative frequency band (IFB).

In this section, the authors present the results of the cyclostationary analysis of the described signals. The bi-frequency maps enable us to visualize the data more clearly and understand their character. They also allow us to describe the differences between the signals.

Figure  presents CSC maps calculated based on signals from a healthy bearing (panel a) and from a bearing with an inner race fault (panel b). The signal from the healthy bearing contains one major component visible on the map: a cycle of 24.97 Hz and its multiples. This component describes the rotational frequency of the motor shaft.

The signal from the bearing with the inner race fault presents a more complicated structure. Similarly to the healthy bearing, we can observe the component at 24.97 Hz and its multiples; however, the predominant cycle has a frequency of 135.2 Hz (and its multiples), which correctly corresponds to the inner race fault. In this signal, sidebands also appear on the CSC map. For example, the component at 110 Hz is clearly visible on the map, and this component is the first left-hand sideband of the central frequency of 135 Hz (inner race fault) with a distance of 25 Hz (shaft cycle).

Figure  presents CSC maps calculated based on signals from bearings with large (panel a) and small (panel b) outer race faults. On both maps, the predominant component describes the 89.5 Hz cycle (and its multiples) that correctly describes the characteristic frequency of the outer race fault. The main difference between those two faults is clearly visible on the maps. It manifests mainly as a difference in the carrier frequency band occupied by the fringes describing the fault component. The value of the fringes also differs and is stronger for the larger fault.

Unfortunately, the structure of the bi-frequency map for all experiments with an inverter-powered motor is significantly different (see Figs.  and ). A dominant component on the map is related to 50 Hz and is harmonics (100, 150, etc.). These components are critical for the small outer bearing fault case where the map is completely dominated by 50 Hz and the fault signature is barely visible (limited band, smaller amplitudes). One may conclude that the same fault is much more difficult to detect in the case of using an inverter.

Figures  and  present the enhanced envelope spectra (EES) calculated based on CSC maps from Figs. , , , and . This representation allows us to observe and interpret the information more simply and directly. Furthermore, those plots allow us to confirm and emphasize the information presented on the CSC maps.

Figure  presents the EES plots for signals measured using a grid-powered setup. Regarding the signal from a healthy bearing, only the four shaft-related components can be observed (the rest are masked by other components). The EES related to the inner race fault exhibits clear peaks that describe the fault. One can also identify peaks at the first three harmonic frequencies related to the shaft cycle, as well as sidebands around fault harmonics that are related to the shaft cycle (i.e., 135 Hz ± 25 Hz). A similar situation can be observed at EES plots regarding both outer race faults. Peaks describing fault harmonics are clearly visible above all other components. One can identify two or three shaft-related harmonics, and shaft-related sidebands can also be observed.

Figure  presents the EES plots for signals measured using an inverter-powered setup. Regarding signal from a healthy bearing, the situation is similar to the grid-powered setup (shaft-related frequencies are visible), but in this case, components at multiples of 50 and 100 Hz are significantly stronger than all other multiples of 25 Hz. For the inner race fault, the structure of EES for grid power and inverter power is very similar; however, for inverter power, the overall scale of EES is visibly smaller. On the other hand, the EES plots for both outer race faults are significantly different from those for grid-powered scenarios. Besides the same fault-related components that are visible in grid-powered case, now one can observe a significant presence of frequencies that are multiples of 100 and 50 Hz, with a structure similar to the one observed at the EES of a healthy bearing (multiples of 100 Hz are significantly stronger than multiples of 50 Hz). However, fault-related components are still clearly visible.

Figures  and  present the same CSC maps as shown before but with a three-dimensional viewing perspective. Such a viewing mode allows us to visualize better the relation between the values of noise floor fluctuations (non-informative areas) and the values of the actual modulation-related fringes at the expected modulation frequencies (informative areas). Especially for cases of inner ring fault (for both grid and inverter power) one can see that there are values of significant amplitudes scattered all over these maps. It is an important observation since, for further investigation of such cases, one might need to incorporate additional steps in the processing procedure, such as denoising or filtration. However, the remaining cases (healthy bearings or outer race faults) seem to produce much cleaner CSC maps with significantly less contaminated, non-informative areas.

In Fig. , a basic feature is presented that accumulates all the information into one value. One can see that introducing a fault in the bearing causes an increase in amplitudes on the map, indicating that the value of the feature is higher than in a healthy state. A small outer race fault provides a relatively small increase in the value of the feature. It is worth noting that even under good conditions, there are many components with relatively small amplitudes (related to the shaft and others), so their accumulation results in relatively high background noise.

Another interesting observation can be made: although inverter-powered scenarios seem to produce CSC maps and EES spectra that contain significantly more components in relation to the grid-powered scenarios, a comparison of the four inverter-powered cases with respective grid-powered cases shows that the overall sums of value aggregation are lower.

Finally, one can make a third observation: for the grid-powered case, a small fault of the outer race produces a sum value that is minimally larger than for the healthy bearing. However, in the case of the inverter-powered scenario, the same low-level fault of the outer race produces a sum value that is significantly lower than for the healthy bearing. In particular, for a grid-powered scenario, the difference in values is equal to 3.58×102, which constitutes a positive difference of 1.85%. However, for an inverter-powered scenario, the difference in values is equal to 2.34×103, which represents a negative difference of 15.49%.

Figure  presents the values of the EENVSI indicator for the eight cases presented. One can make two clear observations, as follows.

For both grid-powered and inverter-powered cases, signals measured on faulty bearings produce higher values of EENVSI than signals measured on healthy bearings.

Similarly to the EENVSI, Fig.  shows that the entropy of the CSC maps also takes lower values for configurations with the inverter compared to the grid-power setup for all four scenarios (). The same effect can be observed for peak SNR in Fig. .

Even an electric motor with good-condition bearings produces a cyclostationary signal with a complicated harmonic structure. Introducing a fault to the bearing delivers cyclic components related to the frequency of the fault (inner, outer). The amount of damage influences the structure of the map. One may summarize that for electric motors powered by the electric grid, bearing fault detection is not so complicated; however, it requires the smart integration of the kind of envelope spectrum or even the extraction of scalar features. Unfortunately, an electric motor driven by an inverter seems to be much more challenging. The inverter produces a significantly higher level of raw signal, which masks the informative component related to the damaged bearing. Moreover, a bi-frequency map contains a family of components with much higher amplitudes than the fault signature. The relation between informative and noninformative components is much worse in the case of a motor driven by an inverter. One may observe that an inverter introduces numerous non-informative components, which decrease the signal-to-noise ratio. What is important is that the estimated amplitudes of fault components are smaller in the case of a motor driven by an inverter. This means that disturbances introduced by the inverter increase background noise (noninformative components) but also influence values of informative components that may have critical importance for decision-making.

Our observations open up new research directions related to the development of smart integration into the envelope spectrum and the statistical analysis of the map to detect informative components.

Cyclostationary analysis is well-known in the condition-monitoring community; however, its application in bearing diagnostics for electric drives has not been as frequent until now. Several journal papers proposed methods based on the cyclostationary approach; however, none of them deeply studied the structure of the CSC map before the stage of feature extraction and decision-making.

In this paper, the authors conducted a simple experiment in the lab using a test rig driven by a grid and an inverter. Four different bearing conditions have been investigated (healthy, inner race fault, small outer race fault, and large outer race fault). The purpose of this work was to study the structure of the map and to investigate the feasibility of utilizing basic features that can be extracted from it.

It was observed that the source of energy for the electric drive is critically important for cyclostationary analysis. The inverter introduces non-informative components (from a fault detection perspective) that make the map less readable. Furthermore, the amplitudes of the components related to the fault frequency are smaller than in the case powered by the grid. Additionally, some additional components related to the shaft imbalance have been identified. These facts require a redefinition of the feature-extraction procedure and a robust fault detection method.

It has been confirmed that introducing damage to the tested bearings generates components on a bi-frequency map at the fault frequency and its harmonics. The structure of the spectral signature of the fault follows the theoretical expectation. An increase in the size of the fault leads to an increase in the signature. In this paper, it has been shown that this is not exactly the case for an electric motor powered by an inverter. In general, the rule remains valid but cannot be applied directly to the grid and inverter cases. Moreover, a signature integrated to the 1D scalar value showed that a small outer fault provides a signature smaller than that of healthy conditions. Even though the global cyclostationary indicator is slightly smaller for the inverter case, the normalized feature (EENVSI) showed significantly worse performance for the inverter-driven motor. The normalized cyclostationary indicator enables tracking fault development; however, its values for the inverter are smaller than those for the grid case. This means a smaller effectiveness of fault detection in this case.

It was believed that cyclostationary analysis is suitable for detecting mechanical faults in rolling bearings, as it can easily identify a nonlinear interaction between the modulating frequency (related to the fault) and the carrier frequency (related to the natural frequency). The amplitude of the component on the bi-frequency map should be proportional to the size of the fault. It should not depend on the type of power supplier.

Cyclostationary analysis for vibration signals from rolling element bearings in electric drives with inverters requires deep investigation into the interpretation of the structure of the map and feature-extraction procedures. It is noteworthy that it cannot be a simple aggregation that globally assesses the map (such an approach could be interesting from the perspective of online condition-monitoring systems). Even classical integration procedures that transform a 3D map to a 2D envelope spectrum may provide an accumulation of disturbances and decision-making with high uncertainty. In the considered cases, it has been observed that the additional components are wideband and significantly visible in the maps, which makes a lot of standard approaches unsuitable (i.e., IFB selection, considering the strongest cyclic components, etc.). Additionally, it has been observed that even the same configuration powered by the grid or by the inverter presents very different characteristics, and even parameterization with appropriate metrics shows that they cannot be analyzed in the same way (i.e. different decision thresholds are required, different class separation intervals can cause a different classifier to be required, etc.). The contribution of this paper lies in explaining the structure of CSC map in a scenario of the diagnostics of bearings in the induction motors (operating with and without an inverter), and it can be considered a very preliminary step for proposing automatic diagnostic techniques.