Sage Journals: Discover world-class research

Abstract

Since obtaining the undamaged structural response information is challenging in practice, damage identification methods relying on undamaged response data face significant limitations in engineering applications. Furthermore, issues such as the influence of measurement noise, high computational costs, and the weak theoretical interpretability of damage identification methods constrain the development and application of structural health monitoring technologies. This paper aims to develop a simple, effective, and noise-resistant method for identifying structural nonlinear damage. To achieve this goal, a structural nonlinear damage identification method is proposed by combining the strong noise resistance of higher-order spectra with the advantages of the autoregressive (AR) model, which has clear physical interpretability and low computational cost. The proposed method establishes an AR model for the structural acceleration response, and regards the bispectral image fluctuation level of AR model residuals as a damage-sensitive feature, developing a damage indicator based on this feature for nonlinear damage localization. The analytical validation was conducted separately using nonlinear damage experiment data from the three-story frame model at Los Alamos National Laboratory and a scaled relay tower model. The analysis results verify that the proposed method can effectively identify and characterize nonlinear features within structural acceleration response. It can accurately identify nonlinear features caused by breathing cracks and bolt looseness, and efficiently determine the location of structural nonlinear damage sources.

Keywords

Damage identification higher-order spectral analysis time series analysis nonlinear damage experimental study

Get full access to this article

View all access options for this article.

References

Chen

Mei

, et al. Study on the sensitive factors of structural nonlinear damage based on the innovation series. Int J Struct Stab Dyn 2020; 20(10): 2042011.

Mattei

de Melo

Bueno

DD.

On the use of parallel full-order state observers for damage detection in mechanical systems. J Braz Soc Mech Sci Eng 2021; 43(12): 556.

Adams

Farrar

CR.

Classifying linear and nonlinear structural damage using frequency domain ARX models. Struct Health Monit 2002; 1(2): 185–201.

Sun

Jiang

, et al. Signal-segments cross-coherence method for nonlinear structural damage detection using free-vibration signals. Adv Struct Eng 2020; 23(6): 1041–1054.

Lakshmi

Keerthivas

Damage diagnosis of high-rise buildings under variable ambient conditions using subdomain approach. Inverse Probl Sci Eng 2021; 29(13): 2579–2610.

Gul

Catbas

FN.

Statistical pattern recognition for structural health monitoring using time series modeling: theory and experimental verifications. Mech Syst Signal Process 2009; 23(7): 2192–2204.

Zheng

Mita

Localized damage detection of structures subject to multiple ambient excitations using two distance measures for autoregressive models. Struct Health Monit 2009; 8(6): 207–222.

Mei

Zhou

, et al. Output-only damage detection of shear building structures using an autoregressive model-enhanced optimal subpattern assignment metric. Sensors 2020; 20(7): 2050.

Nair

Kiremidjian

Law

. Time series-based damage detection and localization algorithm with application to the ASCE benchmark structure. J Sound Vib 2006; 291(1–2): 349–368.

10.

Gul

A time series based damage detection method for obtaining separate mass and stiffness damage features of shear-type structures. Eng Struct 2020; 208: 109914.

11.

Umar

Vafaei

Alih

SC.

Sensor clustering-based approach for structural damage identification under ambient vibration. Autom Constr 2021; 121: 103433.

12.

Cheng

Chen

LJ.

Structural nonlinear damage detection based on ARMA-GARCH model. Appl Mech Mater 2012; 1975: 2891–2896.

13.

Guo

H-Y

Zuo

Structural nonlinear damage identification using penalty conversion index of GARCH model. Adv Mech Eng 2020; 12(11): 1687814020971173.

14.

Cheng

Guo

Wang

YS.

Structural nonlinear damage detection method using AR/ARCH model. Int J Struct Stab Dyn 2017; 17(8): 1750083.

15.

Chandran

Elgar

A general procedure for the derivation of principal domains of higher-order spectra. IEEE Trans Signal Process 1994; 42(1): 229–233.

16.

Sinha

Yunusa-Kaltungo

Combined bispectrum and trispectrum for faults diagnosis in rotating machines. Proc Inst Mech Eng Pt O J Risk Reliab 2014; 228(4): 419–428.

17.

Hashempour

Agahi

Mahmoodzadeh

A novel method for fault diagnosis in rolling bearings based on bispectrum signals and combined feature extraction algorithms. Signal Image Video Process 2022; 16: 1043–1051.

18.

Guo

Yang

, et al. A local modulation signal bispectrum for multiple amplitude and frequency modulation demodulation in gearbox fault diagnosis. Struct Health Monit 2023; 22(1): 1–17.

19.

Zou

Zhang

Jiang

, et al. Toward accurate extraction of bearing fault modulation characteristics with novel time-frequency modulation bispectrum and modulation Gini index analysis. Mech Syst Signal Process 2024; 219: 111629.

20.

Gunasegaran

Amarnath

Chelladurai

Assessment of local faults in helical geared system using vibro-acoustic signals based on higher order spectrum analysis. Appl Acoust 2023; 204: 109237.

21.

Prawin

Rao

Detection and quantification of non-linear structural behavior using frequency domain methods. Res Nondestruct Eval 2020; 31(2): 69–106.

22.

Zhao

Linsheng

Song

Vibration acoustic modulation for bolt looseness monitoring based on frequency-swept excitation and bispectrum. Smart Mater Struct 2023; 32(3): 034004.

23.

Gelman

Kırlangıç

AS.

Novel vibration structural health monitoring technology for deep foundation piles by non-stationary higher order frequency response function. Struct Control Health Monit 2020; 27: e2526.

24.

Kırlangıç

AS.

Nonlinear vibration based estimation of corrosion induced deterioration in reinforced concrete. J Civ Struct Health Monit 2020; 10: 639–651.

25.

Barbieri

Silva

HAT

. A methodology for identification of damage in beams. Inverse Probl Sci Eng 2016; 24(3): 482–503.

26.

Akaike

Maximum likelihood identification of gaussian autoregressive moving average models. Biometrika 1973; 60(2): 255–265.

27.

Zhou

Chen

Dong

, et al. Application of the horizontal slice of cyclic bispectrum in rolling element bearings diagnosis. Mech Syst Signal Process 2012; 26: 229–243.

28.

Figueiredo

Park

Figueiras

, et al. Structural health monitoring algorithm comparisons using standard data sets. Los Alamos, NM: Los Alamos National Laboratory, 2009.

29.

Zuo

Guo

H-Y.

Structural Nonlinear damage identification method based on the Kullback–Leibler distance of time domain model residuals. Remote Sens 2023; 15(4): 1135.

30.

Zuo

Guo

H-Y.

Structural nonlinear damage identification based on Bayesian optimization GNAR/GARCH model and its experimental study. Structures 2022; 45: 867–885.

A methodology for structural nonlinear damage identification using higher-order spectral analysis of time series

Abstract

Keywords

Get full access to this article

References