A robust hybrid hidden Markov model-based fault detection method is proposed to perform multi-state fault classification of rotating components. The approach presented in this paper enhances the performance of the standard hidden Markov model (HMM) for fault detection by performing a series of pre-processing steps. First, the de-noised time-scale signatures are extracted using wavelet packet decomposition of the vibration data. Subsequently, the Teager Kaiser energy operator is employed to demodulate the time-scale components of the raw vibration signatures, following which the condition indicators are calculated. Out of several possible condition indicators, only relevant features are selected using a decision tree. This pre-processing improves the sensitivity of condition indicators under multiple faults. A Gaussian mixing model-based hidden Markov model (HMM) is then employed for fault detection. The proposed hybrid HMM is an improvement over traditional HMM in that it achieves better separation of the feature space leading to more robust state estimation under multiple fault states and measurement noise scenarios. A simulation employing modulated signals and two experimental validation studies are presented to demonstrate the performance of the proposed method.
AkaikeH (1974) A new look at the statistical model identification. IEEE Transactions on Automatic Control19: 716–723.
2.
BaruahPChinnamRB (2005) HMMs for diagnostics and prognostics in machining processes. International Journal of Production Research43(6): 1275–1293.
3.
BoutrosTLiangM (2011) Detection and diagnosis of bearing and cutting tool faults using hidden Markov models. Mechanical Systems and Signal Processing25(6): 2102–2124.
4.
Breiman L, Friedman JH, Olshen RA, et al. (1984) Classification and regression trees. Technical Report, 7–10 February. Belmont: Wadsworth International Group.
5.
BunksCMccarthyD (2000) Condition-based maintenance of machines using hidden Markov models. Mechanical Systems and Signal Processing14(4): 597–612.
6.
ChinSCRayARajagopalanV (2005) Symbolic time series analysis for anomaly detection: A comparative evaluation. Signal Processing85: 1859–1868.
FengZFuleiCZuoMJ (2011) Time-frequency analysis of time-varying modulated signals based on improved energy separation by iterative generalized demodulation. Journal of Sound and Vibration330(6): 1225–1243.
9.
GelleGColasM (2001) Blind source separation: a tool for rotating machine monitoring by vibrations analysis?Journal of Sound and Vibration248(5): 865–885.
10.
HaileMADykasB (2015) Blind source separation for vibration-based diagnostics of rotorcraft bearings. Journal of Vibration and Control. 1–14. DOI: 10.1177/1077546314566041. .
11.
Howard I (1994) A review of rolling element bearing vibration: Detection, diagnosis and prognosis. DSTO-AMRL report, DSTO-RR-00113, pp. 115–121.
12.
JardineAKSLinDBanjevicD (2006) A review on machinery diagnostics and prognostics implementing condition-based maintenance. Mechanical Systems and Signal Processing20: 1483–1510.
13.
JianRLiuSTangYet al. (2015) A novel method of fault diagnosis for rolling element bearings based on the accumulated envelope spectrum of the wavelet packet. Journal of Vibration and Control21(8): 1580–1593.
14.
JiangHLiCLiH (2013) An improved EEMD with multiwavelet packet for rotating machinery multi-fault diagnosis. Mechanical Systems and Signal Processing36(2): 225–239.
15.
JunshengCDejieYYuY (2007) The application of energy operator demodulation approach based on EMD in machinery fault diagnosis. Mechanical Systems and Signal Processing21: 668–677.
16.
Kaiser JF (1993) Some useful properties of Teager's energy operators. Proceedings of the IEEE International Conference on Acoustics, Speech and Signal Processing 3: 149-152.
17.
LeeSLiLNiJ (2010) Online degradation assessment and adaptive fault detection using modified hidden Markov model. Journal of Manufacturing Science and Engineering, ASME132(2): 11.
18.
LeiYLinJHeZet al. (2013) A review on empirical mode decomposition in fault diagnosis of rotating machinery. Mechanical Systems and Signal Processing35(1–2): 108–126. .
19.
LiCLiangM (2012) Time-frequency signal analysis for gearbox fault diagnosis using a generalized synchrosqueezing transform. Mechanical Systems and Signal Processing26(0): 205–217.
20.
LiZHeYChuFet al. (2006) Fault recognition method for speed-up and speed-down process of rotating machinery based on independent component analysis and factorial hidden Markov model. Journal of Sound and Vibration291: 60–71.
21.
LiZWuZHeYet al. (2005) Hidden Markov model-based fault diagnostics method in speed-up and speed-down process for rotating machinery. Mechanical Systems and Signal Processing19: 329–339.
22.
LiangMBozchalooiS (2010) An energy operator approach to joint application of amplitude and frequency-demodulations for bearing fault detection. Mechanical Systems and Signal Processing24: 1473–1494.
23.
LiuJWangWMaF (2011) Bearing system health condition monitoring using a wavelet cross-spectrum analysis technique. Journal of Vibration and Control18(7): 953–963.
24.
LiuQDongMPengY (2012) A novel method for online health prognosis of equipment based on hidden semi-Markov model using sequential Monte Carlo methods. Mechanical Systems and Signal Processing32(0): 331–348.
25.
LiuTChenJDongG (2013) Singular spectrum analysis and continuous hidden Markov model for rolling element bearing fault diagnosis. Journal of Vibration and Control. 1–16. DOI: 10.1177/1077546313496833. .
26.
MallatSG (1998) A wavelet tour of signal processing, San Diego: Academic Press.
27.
McLachlanG (1998) Mixture Models, New York: Marcel Dekker.
28.
MiaoQMakisV (2007) Condition monitoring and classification of rotating machinery using wavelets and hidden Markov models. Mechanical Systems and Signal Processing21: 840–855.
29.
NelwamondoFVMarwalaTMaholaU (2005) Early classifications of bearing faults using hidden Markov models, gaussian mixture models, mel-frequency cepstral coefficients and fractals. Journal of Innovative Computing Information and Control2(6): 1281–1299.
30.
NguyenVHGolinvalJC (2010) Fault detection based on kernel principal component analysis. Engineering Structures32(11): 3683–3691.
31.
NguyenVHRuttenCGolinvalJC (2012) Fault diagnosis in industrial systems based on blind source separation techniques using one single vibration sensor. Shock and Vibration19: 795–801.
32.
OcakHLoparoKA (2005) HMM-based fault detection and diagnosis scheme for rolling element bearings. Journal of Vibration and Acoustics127(4): 299–306.
33.
OwsleyLMDAtlasLEBernardGD (1997) Self-organizing feature maps and hidden Markov models for machine-tool monitoring. IEEE Transactions on Signal Processing45(11): 2787–2798.
34.
PengZChuF (2004) Application of the wavelet transform in machine condition monitoring and fault diagnostics: A review with bibliography. Mechanical Systems and Signal Processing18(2): 199–221.
35.
PesquetJCKrimHCarfantanH (1996) Time-invariant orthonormal wavelet representations. IEEE Transactions in Signal Processing44(8): 1964–1970.
36.
QuinlanJR (1993) C4.5: programs for machine learningVol. 1, San Francisco, CA, USA: Morgan Kaufmann Publishers Inc.
37.
RabinerLR (1989) A tutorial on hidden Markov models and selected applications in speech recognition. Proceedings of the IEEE77(2): 257–287.
38.
RodriguezPHAlonsoJBFerrerMAet al. (2013) Application of the Teager–Kaiser energy operator in bearing fault diagnosis. ISA Transactions52: 278–284.
39.
SharmaAAmarnathMKankarPK (2014) Feature extraction and fault severity classification in ball bearings. Journal of Vibration and Control. 1–17. DOI: 10.1177/1077546314528021. .
40.
SmythP (1994) Hidden Markov models for fault detection in dynamic systems. Pattern Recognition27(1): 149–164.
41.
TimuskMLipsettMMechefskeCK (2008) Fault detection using transient machine signals. Mechanical Systems and Signal Processing22: 1724–1749.
42.
WickerhauserM (1994) Adapted Wavelet Analysis from Theory to Software, Wellesley: AK Peters, Ltd.
43.
YanRGaoRXChenX (2014) Wavelets for fault diagnosis of rotary machines: A review with applications. Signal Processing96(Part-A): 1–15.
44.
ZhaoXPatelTHZuoMJ (2012) Multivariate EMD and full spectrum based condition monitoring for rotating machinery. Mechanical Systems and Signal Processing27(0): 712–728.
45.
ZhouWKovvaliNReynoldsWet al. (2009) On the use of hidden Markov modeling and time-frequency features for damage classification in composite structures. Journal of Intelligent Material Systems and Structures20(11): 1271–1288.
46.
ZhuZFengZKongF (2005) Cyclostationarity analysis for gearbox condition monitoring: Approaches and effectiveness. Mechanical Systems and Signal Processing19(3): 467–482.
47.
ZiajaAAntoniadouIBarszczTet al. (2014) Fault detection in rolling element bearings using wavelet-based variance analysis and novelty detection. Journal of Vibration and Control. 1–16. DOI: 10.1177/1077546314532859. .
